Underwater sound localization of pure tones in the median plane by harbor seals (Phoca vitulina)

How harbour seals (Phoca vitulina) encode goals relative to landmarks

Visual landmarks are defined as object with prominent shape or size that distinguish themselves from the background. With the help of landmarks, animals can orient themselves in their natural environment. Yet, the way in which landmarks are perceived and encoded has previously only been described in insects, fish, birds, reptilians and terrestrial mammals. The present study aimed to provide insight into how a marine mammal, the harbour seal, is encoding goals relative to landmarks. In our expansion test, three harbour seals were trained to find a goal inside an array of landmarks. After diagonal, horizontal or vertical expansion of the landmark array, the search behaviour displayed by the animals was documented and analyzed regarding the underlying encoding strategy. The harbour seals mainly encoded directional vector information from landmarks and did neither search arbitrarily around a landmark nor used a rule-based approach. Depending on the number of landmarks available within the array, the search behaviour of some harbor seals changed, indicating flexibility in landmark-based search. Our results present first insight in how a semi-aquatic predator could encode landmark information when swimming along the coastline in search for a goal-location.

Underwater sound localization abilities of harbor seals (Phoca vitulina) for high-frequency noise band stimuli in the median plane

Pinnipeds use a variety of acoustic information underwater for social interactions, hunting, and predator avoidance. Thus, the ability to accurately localize a sound source in the environment can have a clear survival value. Nonetheless, the sound localization mechanisms for seals underwater still have to be clarified, especially for sounds received in the median plane. In this study, the sound localization abilities of five harbor seals for high-frequency noise band stimuli were measured underwater in the median plane. The seals' minimum audible angles (MAAs) were determined for two different high-frequency noise band stimuli using a two-alternative forced-choice procedure. Noise 1 had a frequency range between 8 and 16 kHz. Noise 2 contained frequencies between 14 and 16 kHz. Psychoacoustic results for the tested harbor seals show that the seals were able to localize these stimuli in the median plane underwater with MAAs between 5.1° and 17.5°. The results suggest that spectral cues improve the seals' ability to localize high-frequency sound signals in the median plane.