Gap perception in bumblebees

Ravi, Sridhar; Bertrand, O.; Siesenop, Tim; Manz, Lea-Sophie; Doussot, Charlotte; Fisher, Alex; Egelhaaf, Martin

doi:10.1242/jeb.184135

Cited by 36 publications

(37 citation statements)

References 45 publications

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“…One potential hypothesis for why bees, on average, flew more quickly when approaching moving obstacles in wind is that the obstacles' lateral movement provides enhanced visual information (e.g. Kirchner and Srinivasan, 1989;Srinivasan et al, 1996) that bees would normally gather by slowing down and performing lateral casting motions (Ravi et al, 2019), and this allowed the bees to traverse moving obstacles without slowing to gather this information. However, if this were true, we would expect to have seen the same result in still air (i.e.…”

Section: Discussionmentioning

confidence: 99%

“…We analyzed the final 50 mm of each approach (longitudinal distance along the axis of the tunnel) because this is the region in which bees were expected to display strong behavioral responses to the obstacles, based on previous studies (e.g. Ravi et al, 2019). When bees were approaching obstacles in a headwind, the filmed approach region would lie entirely within the wake produced by the obstacles, as vortices shed from obstacles in wind at this Reynolds number (∼240) create a turbulent wake downstream for distances >50 mm (e.g.…”

Section: Kinematic Analysismentioning

confidence: 99%

“…We calculated the median ground speed (speed relative to the ground, not incorporating flow velocity) of each approach, based on the velocity of the bees within the horizontal plane (i.e. incorporating movement along the lateral and longitudinal axes of the tunnel, but ignoring vertical motion; Baird and Dacke, 2012;Mountcastle et al, 2016;Ravi et al, 2019).…”

Section: Kinematic Analysismentioning

confidence: 99%

“…When bees approach an obstacle directly in front of them, they can decelerate smoothly to land on the obstacle by maintaining a constant apparent rate of image expansion (Baird et al, 2013), although this strategy is not always observed in the presence of wind (Chang et al, 2016). Additionally, bees may cast from side to side when approaching obstacles, presumably to gather visual information about the obstacle (Ravi et al, 2019). Bees also perform braking maneuvers, in which they increase their body pitch angle and reverse direction to avoid collisions with obstacles (Crall et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Wind and obstacle motion affect honeybee flight strategies in cluttered environments

Burnett

Badger

Combes

2020

Journal of Experimental Biology

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Bees often forage in habitats with cluttered vegetation and unpredictable winds. Navigating obstacles in wind presents a challenge that may be exacerbated by wind-induced motions of vegetation. Although wind-blown vegetation is common in natural habitats, we know little about how the strategies of bees for flying through clutter are affected by obstacle motion and wind. We filmed honeybees Apis mellifera flying through obstacles in a flight tunnel with still air, headwinds or tailwinds. We tested how their ground speeds and centering behavior (trajectory relative to the midline between obstacles) changed when obstacles were moving versus stationary, and how their approach strategies affected flight outcome (successful transit versus collision). We found that obstacle motion affects ground speed: bees flew slower when approaching moving versus stationary obstacles in still air but tended to fly faster when approaching moving obstacles in headwinds or tailwinds. Bees in still air reduced their chances of colliding with obstacles (whether moving or stationary) by reducing ground speed, whereas flight outcomes in wind were not associated with ground speed, but rather with improvement in centering behavior during the approach. We hypothesize that in challenging flight situations (e.g. navigating moving obstacles in wind), bees may speed up to reduce the number of wing collisions that occur if they pass too close to an obstacle. Our results show that wind and obstacle motion can interact to affect flight strategies in unexpected ways, suggesting that wind-blown vegetation may have important effects on foraging behaviors and flight performance of bees in natural habitats.

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Section: Discussionmentioning

confidence: 99%

Section: Kinematic Analysismentioning

confidence: 99%

Section: Kinematic Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Wind and obstacle motion affect honeybee flight strategies in cluttered environments

Burnett

Badger

Combes

2020

Journal of Experimental Biology

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“…The habituated bees were allowed to travel through a foraging tunnel (140 × 30 × 30 cm 3 ) connected to the hive box and a foraging chamber via 2.5 cm diameter tubes and acrylic boxes (see Figure 1). The walls of the tunnel were covered with a red and white 1/f noise pattern (as in (Ravi et al, 2019)). When an individually marked bumblebee returned from the foraging chamber, it was rerouted by using small acrylic gates into an experimental tunnel, parallel to the foraging tunnel.…”

Section: Methodsmentioning

confidence: 99%

From Paths to Routes: A Method for Path Classification

Gonsek

Jeschke

Rönnau

et al. 2021

Front. Behav. Neurosci.

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Many animals establish, learn and optimize routes between locations to commute efficiently. One step in understanding route following is defining measures of similarities between the paths taken by the animals. Paths have commonly been compared by using several descriptors (e.g., the speed, distance traveled, or the amount of meandering) or were visually classified into categories by the experimenters. However, similar quantities obtained from such descriptors do not guarantee similar paths, and qualitative classification by experimenters is prone to observer biases. Here we propose a novel method to classify paths based on their similarity with different distance functions and clustering algorithms based on the trajectories of bumblebees flying through a cluttered environment. We established a method based on two distance functions (Dynamic Time Warping and Fréchet Distance). For all combinations of trajectories, the distance was calculated with each measure. Based on these distance values, we grouped similar trajectories by applying the Monte Carlo Reference-Based Consensus Clustering algorithm. Our procedure provides new options for trajectory analysis based on path similarities in a variety of experimental paradigms.

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Visual Processing in Free Flight

Egelhaaf

2022

Encyclopedia of Computational Neuroscience

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Gap perception in bumblebees

Cited by 36 publications

References 45 publications

Wind and obstacle motion affect honeybee flight strategies in cluttered environments

Wind and obstacle motion affect honeybee flight strategies in cluttered environments

From Paths to Routes: A Method for Path Classification

Visual Processing in Free Flight

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