Abstract
Bioacoustic localization of bird vocalizations provides unattended observations of the location of calling individuals in many field applications. While this technique has been successful in monitoring terrestrial distributions of calling birds, no published study has applied these methods to migrating birds in flight. The value of nocturnal flight call recordings can increase with the addition of three‐dimensional position retrievals, which can be achieved with adjustments to existing localization techniques. Using the time difference of arrival method, we have developed a proof‐of‐concept acoustic microphone array that allows the three‐dimensional positioning of calls within the airspace. Our array consists of six microphones, mounted in pairs at the top and bottom of three 10‐m poles, arranged in an equilateral triangle with sides of 20 m. The microphone array was designed using readily available components and costs less than $2,000 USD to build and deploy. We validate this technique using a kite‐lofted GPS and speaker package, and obtain 60.1% of vertical retrievals within the accuracy of the GPS measurements (±5 m) and 80.4% of vertical retrievals within ±10 m. The mean Euclidian distance between the acoustic retrievals of flight calls and the GPS truth was 9.6 m. Identification and localization of nocturnal flight calls have the potential to provide species‐specific spatial characterizations of bird migration within the airspace. Even with the inexpensive equipment used in this trial, low‐altitude applications such as surveillance around wind farms or oil platforms can benefit from the three‐dimensional retrievals provided by this technique.
Highlights
A core problem for research on nocturnal migration for the past century has been validation of abundance, distribution, and species composition of animals aloft (Kunz et al, 2008)
We present a method for estimating the position of birds producing nocturnal flight calls, which will increase their value for describing the spatiotemporal distribution of these species-specific vocalizations
We focus on the time difference of arrival (TDOA) method, which has been successfully transitioned to a number of biological applications including monitoring marine (Clark & Ellison, 2000; Giraudet & Glotin, 2006; Muanke & Niezrecki, 2007; Nosal, 2013) and terrestrial wildlife (Collier et al, 2010; Magyar et al, 1978; Spiesberger & Fristrup, 1990)
Summary
A core problem for research on nocturnal migration for the past century has been validation of abundance, distribution, and species composition of animals aloft (Kunz et al, 2008). Techniques for migration monitoring have incorporated observations from radar, thermal imaging, and audio recordings, but only the analysis of night flight calls can provide taxonomic identity of migrants For this reason, nocturnal flight call data are often used to provide species composition or relative abundance estimates in concert with more robust methods of. The acoustic recorders must be in close proximity to the flying bats to ensure detectability of their ultrasonic calls, resulting in relatively small spatial coverage (e.g., Fujioka, Aihara, Sumiya, Aihara, & Hiryu, 2016) The attenuation of such high- frequency calls can be quite severe, with studies showing maximum call detection ranges on the order of several meters in some cases (Jenson & Miller, 1999; Stilz & Schnitzler, 2012). We describe the challenges associated with deploying a setup of this type in the field and offer practical considerations that should be taken into account in designing such experiments
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