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1. Transfer Entropy Analysis of Interactions between Bats Using Position and Echolocation Data

   https://doi.org/10.3390/e22101176  

   Shaffer, Irena; Abaid, Nicole (October 2020, Entropy)

   null (Ed.)

   Many animal species, including many species of bats, exhibit collective behavior where groups of individuals coordinate their motion. Bats are unique among these animals in that they use the active sensing mechanism of echolocation as their primary means of navigation. Due to their use of echolocation in large groups, bats run the risk of signal interference from sonar jamming. However, several species of bats have developed strategies to prevent interference, which may lead to different behavior when flying with conspecifics than when flying alone. This study seeks to explore the role of this acoustic sensing on the behavior of bat pairs flying together. Field data from a maternity colony of gray bats (Myotis grisescens) were collected using an array of cameras and microphones. These data were analyzed using the information theoretic measure of transfer entropy in order to quantify the interaction between pairs of bats and to determine the effect echolocation calls have on this interaction. This study expands on previous work that only computed information theoretic measures on the 3D position of bats without echolocation calls or that looked at the echolocation calls without using information theoretic analyses. Results show that there is evidence of information transfer between bats flying in pairs when time series for the speed of the bats and their turning behavior are used in the analysis. Unidirectional information transfer was found in some subsets of the data which could be evidence of a leader–follower interaction. 

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2. Eavesdropping like a bat: Towards fusing active and passive sonar for a case study in simultaneous localization and mapping

   https://doi.org/10.1049/rsn2.12093  

   Jahromi_Shirazi, Masoud; Abaid, Nicole (May 2021, IET Radar, Sonar & Navigation)

   Abstract Among so‐called active sensors that use self‐generated signals, sonar sensors are more challenging to implement than lidar and radar due in part to their limited angular field of sensing. A common solution to this challenge is scanning sensors that sweep an angular range with successive measurements. However, scanning sensors are particularly problematic for sonar because of the relatively slow sound speed and the inertia of the sonar head. Studies of bat behaviour suggest that bats may eavesdrop on their conspecifics during group flight. In other words, they fuse information gathered by their own active sonar with information they receive by passively listening to peers. Because bats are extremely skilled in using sonar, this behaviour inspired an investigation into whether fusing active and passive sonar can be a solution to the challenges of implementing sonar sensors. A model of fused sensing is defined, and a numerical simulation is used to answer this question on the test bed problem of simultaneous localization and mapping (SLAM). The simulation results show that when the angular range of active sonar and associated noise is relatively small, the robot's performance in solving SLAM is improved. 

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3. Echolocating bats inspect and discriminate landmark features to guide navigation

   https://doi.org/doi:10.1242/jeb.191965  

   Yu, C.; Luo, J.; Wohlgemuth, M.J.; Moss, C.F. (April 2019, Journal of experimental biology)

   Landmark-guided navigation is a common behavioral strategy for way-finding, yet prior studies have not examined how animals collect sensory information to discriminate landmark features. We investigated this question in animals that rely on active sensing to guide navigation. Four echolocating bats (Eptesicus fuscus) were trained to use an acoustic landmark to find and navigate through a net opening for a food reward. In experimental trials, an object serving as a landmark was placed adjacent to a net opening and an object serving as a distractor was placed next to a barrier (covered opening). The location of the opening, barrier and objects were moved between trials, but the spatial relationships between the landmark and opening, and between the distractor and barrier were maintained. In probe trials, the landmark was placed next to a barrier, while the distractor was placed next to the opening, to test whether the bats relied on the landmark to guide navigation. Vocal and flight behaviors were recorded with an array of ultrasound microphones and high-speed infrared motion-capture cameras. All bats successfully learned to use the landmark to guide navigation through the net opening. Probe trials yielded an increase in both the time to complete the task and the number of net crashes, confirming that the bats relied largely on the landmark to find the net opening. Further, landmark acoustic distinctiveness influenced performance in probe trials and sonar inspection behaviors. Analyses of the animals’ vocal behaviors also revealed differences between call features of bats inspecting landmarks compared with distractors, suggesting increased sonar attention to objects used to guide navigation. 

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4. Going against the flow: bumblebees prefer to fly upwind and display more variable kinematics when flying downwind

   https://doi.org/10.1242/jeb.245374  

   Combes, Stacey A; Gravish, Nick; Gagliardi, Susan F (April 2023, Journal of Experimental Biology)

   ABSTRACT Foraging insects fly over long distances through complex aerial environments, and many can maintain constant ground speeds in wind, allowing them to gauge flight distance. Although insects encounter winds from all directions in the wild, most lab-based studies have employed still air or headwinds (i.e. upwind flight); additionally, insects are typically compelled to fly in a single, fixed environment, so we know little about their preferences for different flight conditions. We used automated video collection and analysis methods and a two-choice flight tunnel paradigm to examine thousands of foraging flights performed by hundreds of bumblebees flying upwind and downwind. In contrast to the preference for flying with a tailwind (i.e. downwind) displayed by migrating insects, we found that bees prefer to fly upwind. Bees maintained constant ground speeds when flying upwind or downwind in flow velocities from 0 to 2 m s−1 by adjusting their body angle, pitching down to raise their air speed above flow velocity when flying upwind, and pitching up to slow down to negative air speeds (flying backwards relative to the flow) when flying downwind. Bees flying downwind displayed higher variability in body angle, air speed and ground speed. Taken together, bees' preference for upwind flight and their increased kinematic variability when flying downwind suggest that tailwinds may impose a significant, underexplored flight challenge to bees. Our study demonstrates the types of questions that can be addressed with newer approaches to biomechanics research; by allowing bees to choose the conditions they prefer to traverse and automating filming and analysis to examine massive amounts of data, we were able to identify significant patterns emerging from variable locomotory behaviors, and gain valuable insight into the biomechanics of flight in natural environments. 

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5. Communication with self, friends and foes by active sensing animals

   https://doi.org/https://doi.org/10.1242/jeb.242637  

   Allen, K.M. (October 2021, Journal of experimental biology)

   Animals that rely on electrolocation and echolocation for navigation and prey detection benefit from sensory systems that operate in the dark, exploiting a sensory niche with few competitors. Active sensing can be described as a highly specialized form of communication, with the self as both sender and receiver of sensory information. However, the overlapping functions of active sensing as communication with the self and active sensing as communication with others creates challenges for signal privacy and fidelity by leaving active sensing animals vulnerable to eavesdropping, jamming, and noise. Here we present an overview of active sensing systems used by weakly electric fish, bats and odontocetes and consider their susceptibility to heterospecific and conspecific jamming signals and eavesdropping. Susceptibility to jamming signals by both conspecifics and prey animals reduces the efficacy of electrolocation and echolocation for prey capture and foraging. Likewise, active sensing signals may be eavesdropped, opening risk of predation or competition at productive foraging sites. The evolutionary success of these animals suggests that they effectively counter the costs of active sensing through rich and diverse adaptive behaviors that allow them to mitigate the effects of competition for signal space and the exploitation of their signals for social communication. 

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