Bio- and Fishery Acoustics

(over a stated time interval) and the standard reference pressure p0 ¼ 1 mPa used in underwater acoustics:  h pi SPL ¼ 20 log10 (12.11) p0 Its units are therefore dB re 1 mPa. For pulsed sounds, the other recommended metrics are the peak SPL, the peakto-peak SPL, the sound exposure level (SEL) for a single pulse, and the cumulative SEL for several pulses, stating clearly how many pulses are considered, how long

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CHAPTER 12 Bio- and Fishery Acoustics

this is considered for (times t1 and t2 in the integral), and the duty cycle of any sampling. Using the same reference pressure of 1 mPa, they can be expressed mathematically as:  ppeak SPLpeak ¼ 20 log10 (12.12) p0  ppp SPLpp ¼ 20 log10 (12.13) p0 R t2 SEL ¼ 10 log10

t1

p2 ðtÞdt

1 mPa2 s

! (12.14)

The frequency distribution of animal and background sounds can amount to large ranges (e.g., up to 200 kHz or beyond), and it is often not feasible to consider the measurements at a 1-Hz accuracy. Instead, third-octave and (sometimes and very rarely) twelfth-octave bands are used. Third-octave bands are defined (ANSI, 2009, in Ref. [90]) by their center frequencies fc (referred to f0 ¼ 1 kHz) and their lower and upper bounds, respectively, f and fþ: 8 ( i1 > i  1 for fc  f0 > > > > fc ¼ f0  10 10 ; i˛ℕ and > > > i < 1 for fc < f0 > > < 1 (12.15) > > 20 > f ¼ f  10 þ c > > > > > 1 > >  : f ¼ fc  10 20 Measurements over third-octave bands (or any frequency band) are expressed as spectral density levels: the amplitude values are divided by the frequency bandwidth, resulting in units of dB re 1 mPa2/Hz (sometimes seen as dB re 1 mPa/Hz1/2). These different metrics can then be used to assess the contributions from the background (using the Wenz curves, seen in Chapter 6, for natural sources) and to compare different sources of noise (e.g., animals vs. shipping or other offshore activities). All sound levels measured in PAM systems are received levels (RL); some applications might require knowledge of the actual SLs, generally at a reference distance of 1 m. Other applications might require understanding of how RL at the range measured would change if measured at another location (e.g., assessing risks to marine mammals at different ranges from a loud source). SL can be obtained by measuring closer to the source, although this is not possible for larger sources (whose contributions cannot be reduced to a single point source at short ranges) or if the survey has already been completed. In most cases, one needs to backpropagate RLs to a generic SL, using the results from Chapters 2 and 3, with those of Chapter 7 as appropriate. Again, clear reporting of the parameters used in

12.7 Selected Practical Applications

modeling acoustic propagation is essential for intercomparison of the final results. This modeling generally requires knowledge of other environmental conditions [91], including bathymetry and seabed types, and information about other loud sources in the vicinity, for example, ships monitored with automatic identification system (AIS) transponders.

12.7 SELECTED PRACTICAL APPLICATIONS 12.7.1 ACTIVE ACOUSTICS: FISH SURVEY The most common application of fishery acoustics is the surveying of commercial fish stocks [9]. This requires measuring the abundance of the species of interest, locating the largest concentrations of fish and how they vary with seasons and weather, and to determine the age/sex/maturity distribution of these species, to assess commercial viability [92]. These aims have considerable challenges. Measurements of fish numbers is often estimated from surveying along lines, keeping in mind that fish are sensitive to noise and are reputed to swim away from ships. Not all seasons are suitable for surveys, meaning that variations in fish abundance with time and weather need to be accounted. And although the exact type of fish and their maturity/size can be estimated from their acoustic scattering (Section 12.3), these need to be calibrated with trawls or optical imaging. There are many models of survey design, depending on platform(s) and instrument(s) available and on costs, which can quickly escalate. Optimization of the survey design can now make use of geographical information systems; a workshop convened by ICES in 2005 [93] published a decision tree to adapt a potential survey to measure the abundance of a single fish species2. Logistics can sometimes result in one survey being achieved with several vessels, potentially with different instruments. The acoustic measurements are then averaged along specific lengths of the survey track, called the elementary distance sampling unit (EDSU). It should be small enough to capture the key spatial elements of the species of interest, but large enough that intrinsic variability does not obscure statistical analyses. This results in typical EDSU values in the range 1e5 km, with extremes at 0.1 km (for dense schools in tight spaces like a fjord) and 9 km (for sparse deep-sea species) [92]. Water-column echoes from the fish species are isolated through different means (see Ref. [94] for a good illustration), and volume backscattering strengths SV (Section 12.3) are integrated over depths z to produce a nautical area scattering coefficient (NASC), expressed in m2/nmi2: Z Zmax 10SV =10 dz (12.16) NASC ¼ 4 pð1852Þ2 Zmin

2

www.ices.dk/sites/pub/Publication%20Reports/Expert%20Group%20Report/ftc/2005/wksad05.pdf (Figure 11).

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This can then be converted to estimated fish densities r by dividing by the expected backscattering cross-section (in m2) of the species of interest: r¼

NASC 4 phsbs i

(12.17)

Multiplying by the survey area (in square nautical miles) should therefore give an estimate of the abundance. These estimates need to be tempered with several factors. Although fish tend to avoid larger/noisier ships, recent research shows they do not avoid more silent survey vessels [48]. Gimona and Fernandes [95] discussed how to put error bars on sounder biomass estimates, given the spatial patchiness and other unknowns. Acoustic scattering can be difficult to relate to a single fish species, but multifrequency approaches [45] can resolve ambiguities, especially if associated with in situ sampling. D’Elia et al. [96] illustrated this potential by combining results from eight acoustic surveys in the Central Mediterranean, to estimate abundances of sardine, anchovy, horse mackerel, and other species. These surveys took place over 9 years, using different instruments working at 38, 120, and 200 kHz, some of which were not regularly calibrated. They were ground truthed with daytime pelagic trawls at specific times. Volume backscattering strengths SV and NASC values at 38 and 120 kHz were compared, but the three main species could not be distinguished from their acoustic properties alone (as their swim bladders are very similar in shape and size). Further processing with classification trees [94] and bathymetry parameters (e.g., school depths) improved discrimination between these groups to 85% overall. This thorough examination of multiple, carefully designed surveys shows the steps needed to better estimate fish abundance and compare surveys. Research in mid2010s [97] investigated how to incorporate multiple sources of uncertainty in a stock assessment, validating their approach with ICES measurements of the Iberian hake stock.

12.7.2 PASSIVE ACOUSTICS: AMBIENT NOISE MONITORING Accurate knowledge of underwater noise is increasingly required by regulators before approval of offshore projects, from construction of harbor extensions to installation of marine structures, seismic surveying, or new shipping patterns. Understanding baseline noise (before any change in human activity) and how it might evolve later forms a large part of the consenting. Any method that can reliably demonstrate these changes will therefore be welcome. A recent collaboration between the University of Bath and the University of Aberdeen showed how standard PAM could be integrated with automatic identification system (AIS) shipping data, time-lapse video, and meteorological and tide data. This methodology was first presented in Merchant [98], expanded in Pirotta et al. [99] and Merchant et al. [100]. The study site in the Moray Forth (Scotland) is a marine protected area (MPA), with a resident population of bottlenose dolphins (Tursiops truncates) and other protected marine mammal species, such as harbor seal (Phoca vitulina), harbor porpoise

12.7 Selected Practical Applications

(Phocoena phocoena), and gray seal (Halichoerus grypus). The entire area is expected to see developments in shipping density and the expansion of fabrication yards within the MPA, associated to the expansion of the Scottish marine renewable energy industry. Two sites were selected for closer investigation. They were both deep, narrow channels with steep gradients and strong tidal currents. Single PAM devices were deployed for 101 days overall, recording ambient noise at 384 kHz sampling rate, with a duty cycling of 1 min every 10 min. This was synchronized with a time resolution of the AIS data (also recorded every 10 min), provided by third-party network www.shipais.com. Time-lapse footage was recorded from shore, with PAM locations within the field of view of the digital cameras. This allowed identification of vessels with or without AIS, as it is compulsory only for vessels more than 300 GT (gross tons). In two instances, it also identified rigs being moored or towed past (by vessels using dynamic positioning, which produces loud broadband noise). By comparing AIS and acoustic data, it was possible to identify the closest point of approach from a particular vessel to the recording hydrophones, assigning peaks in underwater noise to these vessels (this was possible in about 65% of cases). PAM data was used to calculate 24-h SELs (total SEL, SELs associated to AIS-tracked vessels, and SELs from unidentified sources). Acoustic data (processed with PAMGuard) was also used to detect dolphin clicks and quantify population densities [99]). Additional data used in the analyses included local meteorological data about precipitation and wind speed every 5 min, from the open-access Weather Underground database (www.wunderground. com), and POLPRED tidal computations (at 10 min intervals, to match the acoustic duty cycling). A C-POD was also deployed independently at these two sites, providing additional information about dolphin activity. The methodology (detailed in Merchant [98]) shows the interest of combining different sources of information, acoustic and nonacoustic. This was aided in this case by the proximity to shore, but recent developments in autonomous surface vehicle technology and station-keeping mean that similar information (from time-lapse footage to environmental conditions) can now be acquired further offshore. The main result of this study was that AIS-operating vessels accounted for the total cumulative sound exposure at 0.1e10 kHz, meaning that noise can be modeled using AIS data alone, and that expected noise levels can be calculated using planned increases in shipping patterns (in time and in space). The European Marine Strategy Framework Directive, European Commission [7], recommends the use of the third-octave bands centered on 63 and 125 Hz to assess shipping impacts on noise pollution. Merchant et al. found that the relationship between shipping and noise was stronger at 125 than at 63 Hz, possibly because of tidal flow noise or low-frequency propagation effects in the shallow waters, presented in Chapter 7. Pirotta et al. [99] also found a direct correlation between the presence of moving vessels and the buzzing activity of bottlenose dolphins, suggesting that dolphins perceive shipping as a clear risk as well as an acoustic masker of their own echolocation signals.

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12.7.3 ACOUSTIC TELEMETRY: FISH BEHAVIOR Acoustic tags have been used in many studies of fish behavior [101] and movements of whales [102], and the study selected here looks at the behavior of a relatively large number of fish for a long duration (close to 1 year). MPAs are set up to protect and restore overexploited fish populations. Fish movements occur across different spatial and temporal scales, and they must be understood to assess medium-to long-term MPA efficiency and assist in its management. Aspillaga et al. [103] looked at the white seabream (Diplodus sargus) in a northwest Mediterranean MPA. This is a commercially important fish, highly sedentary and known to shape rocky marine ecosystems. Aspillaga’s study was one of the longest experiments conducted with this type of fish, and it provided a wealth of new, quantitative information. MPA is located around the Medes Islands (NE Spain) and is divided into two zones: no-take, established in 1983 and shown in Fig. 12.18, surrounded by a partial reserve buffer, where very limited fishing is allowed. The seabed habitats are varied and white seabream is known to be more abundant in the no-take zone. Water depths vary between 25 and 65 m, and a particularly severe storm (waves up to 14.4 m high) occurred during the study. Forty-one individual fish were caught and tagged; the acoustic tags were very small and surgically inserted inside the animals (using the best ethical procedure available), and they transmitted at 153 dB. The acoustic monitoring network comprised 27 receivers, most of which are shown in Fig. 12.18. Receivers were moored and placed 8 m below the sea surface: 17 of them within the no-take zone, covering the entire perimeter, and 10 receivers were placed on the mainland shore a few kilometers away. Signal range tests using an acoustic tag as transmitter showed signals could be detected with >90% probability as far as 150 m, after which this dropped to 50%. During the entire monitoring period, 816,250 valid receptions were recorded by the array. Fish in the no-take zone could be tracked for long periods (329  65 days). The residence index of each fish was calculated as the ratio of the number of days it was detected and the total number of monitoring days. All fish proved to be highly territorial, moving within small home ranges (<1 km2), with an average residence index of 0.95  0.0. They displayed repetitive diel activity patterns with 95% of all receptions corresponding to depths of 0.4e11 m below the sea surface. Extraordinary movements beyond the ordinary home range were observed for two occasions: (1) during stormy events, fish quickly sheltered to more protected places; (2) during the spawning season, they moved (up to 400 m away) and aggregated in deep areas (>50 m). These results clearly show the potential of acoustic telemetry with a welldesigned receiver array: individual animals could be tracked over long periods (close to a year) with high (submetric) horizontal and vertical accuracy. The data analysis methodology (fully presented in Aspillaga et al. [103] and supplementary material) provides a robust framework for understanding individual behaviors of any type of fish and population dynamics in baseline and extraordinary (e.g., storm) circumstances. These measurements can also later be used in models of how the effects

12.8 Conclusions: Future Developments

FIGURE 12.18 Marine protected area (MPA) and acoustic receiver array used by Aspillaga et al. [103] to study fish behavior with acoustic telemetry (Reproduced under Creative Commons Attribution License.). The numbers refer to some of the 27 acoustic receivers (numbers not shown were positioned near the mainland, outside the no-take zone and around 1 km away).

of disturbance relate to animal condition/health, environmental variability, bioenergetics, vital rates, and reproductive success (PCoD model: Population Consequences of Disturbance).

12.8 CONCLUSIONS: FUTURE DEVELOPMENTS This chapter aimed to present, through simple concepts and examples, the two connected domains of fishery acoustics and bioacoustics. It started with a simple definition of the different types of marine life (Section 12.2), suitable for

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acousticians, and highlighting the main parameters of interest. Chronologically, the first question faced was how does one detect and monitor fish and other marine life? Section 12.3 looked at acoustic scattering by different animals, from zooplankton to whales, individually and in combination. The different instruments available to detect these animals were presented briefly in Section 12.4, giving only brief examples. How does marine life use sound? How sensitive are animals to other sounds, including man-made? Differences in physiology led to the separate examination of marine mammals, fish, turtles, and invertebrates in Section 12.5. Guidelines for protection of marine animals were introduced. Monitoring of underwater sound, as well as compliance of human activities with existing (and future) regulations are achieved with passive acoustic monitoring (PAM), presented in Section 12.6 Finally, an arbitrary choice of practical applications was presented in Section 12.7, showing the current trends in the use of fishery acoustics (Section 12.7.1), how traditional PAM can be augmented with suitably chosen additional measurements (Section 12.7.2), and how active acoustics (fish tags) and passive acoustics (widely scattered receivers) can be elegantly used to monitor fish behavior over large temporal and spatial scales while still maintaining a very high resolution (Section 12.7.3). The extensive bibliography at the end of this chapter is but a short sample of the very high number of peer-reviewed publications, reports, and opinion pieces written about fishery acoustics and bioacoustics. Search engines indicate both subjects have seen a strong linear growth in publications over the last decades, associated with an exponential increase in citation rates, showing how dynamic these two fields are. It is impossible to do justice to all these interesting studies, but it is worth looking at some future developments, and the questions they pose as of 2016: •

•

• •

•

Acoustic scattering by marine animals is better constrained, for a wide range of frequencies, but there is still significant work to do in benchmarking analytical and numerical models for different species, and variations within each species, as well as making these models computationally fast and approachable by nonspecialists. Target strengths have been measured for many animals in the wild and in the laboratory, but there are still many unknowns, from variations with aspect (e.g., for large animals or even some fish species) to simply any measurement for animals like crocodiles or sea otters. Auditory sensitivity of many animals still needs to be measured, in particular for invertebrates and sea turtles. Identifying scattering by animals close to the sea surface or to the seabed is still a challenge, and so is the identification of multiple species sharing the same space. Accurate tracking of targets of interest across acoustic beams and quantifying the risks of occlusion of one target by a closer one are also open processing problems (other bioacoustics issues are presented in Ref. [104]). New instruments are coming to the fore, from panoramic sonars to multiangle sonars, and coupled with the increased accessibility of autonomous platforms

References

•

•

like autonomous underwater vehicles [105], gliders, and autonomous surface vehicles, new approaches are likely to emerge within the next decade. PAM technology has matured but improvements (e.g., for towed arrays, source localization in complex environments, and transformation of RLs into SLs) are still needed. National and international policies are developing, with the development of marine protected areas (and similarly protected areas), regulations like the European NATURA-2000 or the Marine Strategy Framework Directive, calibration, operation, and analysis standards (e.g., ISO, MEDIN, and JNCC). How much will they be informed by current measurements, and how much will they shape future capabilities and research efforts?

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[13] Foote, K.G., Target strength of fish. In: Encyclopedia of Acoustics, M.J. Crocker (Ed.), Vol. 1, Chapter 44, John Wiley & Sons Ltd., pp. 493e500, 1997. [14] Jech, J.M., Horne, J.K., Chu, D., Demer, D.A., Francis, D.T. I., Gorska, N., Jones, B., Lavery, A.C., Stanton, T.K., Macaulay, G.J., Reeder, D.B., Sawada, K., Comparisons among ten models of acoustic backscattering used in aquatic ecosystem research, J. Acoust. Soc. Am., 138 (6): pp. 3742e3764, 2015. [15] Lavery, A.C., Wiebe, P.H., Stanton, T.K., Lawson, G.L., Benfield, M.C., and Copley, N., Determining dominant scatterers of sound in mixed zooplankton populations, J. Acoust. Soc. Am., 122 (6), pp. 3304e3326, 2007. [16] “Zooplankton - MarineBio.org”. MarineBio Conservation Society. Web. http:// marinebio.org/oceans/zooplankton/. [17] Stanton, T.K., 30 years of advance in active bioacoustics: a personal perspective, Methods Oceanogr., 1e2, pp. 49e77, 2012. [18] Stanton, T.K., Chu, D., Wiebe, P.H., Eastwood, R.L., and Warren, J.D., Acoustic scattering by benthic and planktonic shelled animals, J. Acoust. Soc. Am., 108 (2), pp. 535e550, 2000. [19] Macaulay, G.J., Hart, A.C., Grimes, P.J., Coombs, R., Barr, R., and Dunford, A.J., Estimation of the target strength of oreo and associated species, Final Research Report for Ministry of Fisheries Research Project OEO2000/01A Objective 1. http://fs.fish.govt. nz/Doc/22654/OEO2000-01A%20Oreo%20and %20 Associated %20species% 20Objective%201%20Final.pdf.ashx, 2002. [20] Gødø, O.R., Patel, R., and Pedersen, G., Diel migration and swimbladder resonance of small fish: some implications for analyses of multifrequency echo data., ICES J. Marine Sci., 66, pp. 1143e1148, 2009. [21] Sun Y, Nash R, Clay CS. Acoustic measurements of the anatomy of fish at 220 kHz. J. Acoust. Soc. Am., 78 (5), pp. 1772e1776, 1985. [22] Gorska, N., Ona, E., and Korneliussen, R., Acoustic backscattering by Atlantic mackerel as being representative of fish that lack a swimbladder. Backscattering by individual fish., ICES J. Marine Sci., 62 (5), pp. 984e995, 2005. [23] Davy, C.M., Fenton, M.B., Side-scan sonar enables rapid detection of aquatic reptiles in turbid lotic systems, Eur. J. Wildl. Res., pp. 123e127, 2013. [24] Mahfurdz, A., Sunardi, H. Ahmad, S. Abdullah, and Nazuki, S., Distinguish sea turtle and fish using sound technique in designing acoustic deterrent device, Telkomnika, 13 (4), pp. 1305e1311, 2015. [25] Au, W.W.L., Acoustic reflectivity of a dolphin, J. Acoust. Soc. Am., 99 (6), pp. 3844e3848, 1996. [26] Bernasconi, M., Patel, R., Nottestad, L., Pedersen, G., and Brierley, A.S., Fin whale (Balaenoptera physalus) target strength measurements, Marine Mamm. Sci., 29 (3), pp. 371e388, 2013. [27] Lucifredi, I., and Stein, P.J., Gray whale target strength measurements and the analysis of the backscattered response, J. Acoust. Soc. Am., 121 (3), pp. 1383e1391, 2007. [28] Love, R., Target strengths of humpback whales (Megaptera novaeangliae), J. Acoust. Soc. Am., 54 (5), pp. 1312e1315, 1973. [29] Xu, J., Deng, Z.D., Carlson, T.J., and Moore, B., Target Strength of Southern Resident Killer Whales (Orcinus orca): Measurement and Modeling, Marine Technol. Soc. J., 46 (2), pp. 74e84(11), March/April 2012.

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