A small unmanned aerial system for estimating abundance and size of Antarctic predators

Goebel, Michael E.; Perryman, Wayne L.; Hinke, Jefferson T.; Krause, Douglas J.; Hann, Nancy A.; Gardner, Steve; LeRoi, Donald J.

doi:10.1007/s00300-014-1625-4

Cited by 174 publications

(206 citation statements)

References 37 publications

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“…The authors suggest that flying at 35-40 m above the surface level allows the gathering of important information about size, health, and behavior, while reducing disturbance levels and increasing the measurement precision if compared with manned aircraft [9]. Image resolution (<1.4 cm/pixel with 25 mm lens at 35 m altitude) was slightly lower than what was achieved by Goebel et al [8], but enough to discriminate individuals and detect changes of their body condition during subsequent encounters [9].…”

Section: Abundance Surveys Photogrammetry and Photo-identificationmentioning

confidence: 89%

“…Perryman et al [48] and Goebel et al [8] investigated the use of a small customized hexacopter (APH-22) in the abundance estimation of seals in Antarctica. High-resolution (<1 cm/pixel with 45 mm lens at 45 m altitude) images of the shore were used to count individuals and discriminate pups from adults in fur seal (Arctocephalus gazella) and Weddell seal (Leptonychotes weddellii) colonies.…”

Section: Abundance Surveys Photogrammetry and Photo-identificationmentioning

confidence: 99%

“…In particular, UAS have been proposed as a tool for marine mammal surveys, as they allow researchers to reach remote areas and observe animals from an advantageous perspective, being less invasive than standard aircraft [3][4][5][6][7][8][9]. Despite the challenges of operating at sea [10], UAS have been used for a number of marine mammal research applications, from abundance surveys [8,[11][12][13][14][15][16][17] to the measurement of…”

Section: Introductionmentioning

confidence: 99%

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The Use of Unmanned Aerial Systems in Marine Mammal Research

et al. 2017

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Unmanned aerial systems (UAS), commonly referred to as drones, are finding applications in several ecological research areas since remotely piloted aircraft (RPA) technology has ceased to be a military prerogative. Fixed-wing RPA have been tested for line transect aerial surveys of geographically dispersed marine mammal species. Despite many advantages, their systematic use is far from a reality. Low altitude, long endurance systems are still highly priced. Regulatory bodies also impose limitations while struggling to cope with UAS rapid technological evolution. In contrast, small vertical take-off and landing (VTOL) UAS have become increasingly affordable but lack the flight endurance required for long-range aerial surveys. Although this issue and civil aviation regulations prevent the use of VTOL UAS for marine mammal abundance estimation on a large scale, recent studies have highlighted other potential applications. The present note represents a general overview on the use of UAS as a survey tool for marine mammal studies. The literature pertaining to UAS marine mammal research applications is considered with special concern for advantages and limitations of the survey design. The use of lightweight VTOL UAS to collect marine mammal behavioral data is also discussed.

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Section: Abundance Surveys Photogrammetry and Photo-identificationmentioning

confidence: 89%

Section: Abundance Surveys Photogrammetry and Photo-identificationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Use of Unmanned Aerial Systems in Marine Mammal Research

et al. 2017

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“…UAVs also provide an alternative, safer, quieter and often cost-effective option for monitoring fauna and flora, from individuals and populations to entire ecosystems, and in so doing are replacing expensive manned systems such as helicopters and fixed-wing aircraft Christie et al, 2016). UAV applications in wildlife research now encompass almost all environments, from arid deserts, through rainforests, oceans to polar regions (Linchant et al, 2013(Linchant et al, , 2015Durban et al, 2015;Goebel et al, 2015;Duffy et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…Some examples include, counting elephants (Loxodonta africana) (Linchant et al, 2013;Vermeulen et al, 2013), UAV surveillance (anti-poaching tools) for elephants and rhinoceros (Diceros bicornis and Ceratotherium simum) (Marks, 2014;MuleroPázmány et al, 2014;Hahn et al, 2017), locating chimpanzee nests (Pan troglodytes) (van Andel et al, 2015) and mapping Sumatran orangutan (Pongo abelii) habitat, distribution and density Szantoi et al, 2017). UAV applications now extend to the polar regions where they have been used to monitor and estimate abundance of penguin populations (gentoo, Pygoscelis papua, and chinstrap, Pygoscelis antarctica) and estimate size and condition of leopard seals (Hydrurga leptonyx) (Goebel et al, 2015;Ratcliffe et al, 2015). In the marine environment, UAVs are revolutionizing the way marine species can be studied due to their small size, apparent minimal disturbance of wildlife and improved safety for both operators and animals (Nowacek et al, 2016;Fiori et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

An Economical Custom-Built Drone for Assessing Whale Health

Pirotta

Smith²,

Ostrowski

et al. 2017

Front. Mar. Sci.

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Drones or Unmanned Aerial Vehicles (UAVs) have huge potential to improve the safety and efficiency of sample collection from wild animals under logistically challenging circumstances. Here we present a method for surveying population health that uses UAVs to sample respiratory vapor, 'whale blow,' exhaled by free-swimming humpback whales (Megaptera novaeangliae), and coupled this with amplification and sequencing of respiratory tract microbiota. We developed a low-cost multirotor UAV incorporating a sterile petri dish with a remotely operated 'blow' to sample whale blow with minimal disturbance to the whales. This design addressed several sampling challenges: accessibility; safety; cost, and critically, minimized the collection of atmospheric and seawater microbiota and other potential sources of sample contamination. We collected 59 samples of blow from northward migrating humpback whales off Sydney, Australia and used high throughput sequencing of bacterial ribosomal gene markers to identify putative respiratory tract microbiota. Model-based comparisons with seawater and dronecaptured air demonstrated that our system minimized external sources of contamination and successfully captured sufficient material to identify whale blow-specific microbial taxa. Whale-specific taxa included species and genera previously associated with the respiratory tracts or oral cavities of mammals (e.g., Pseudomonas, Clostridia, Cardiobacterium), as well as species previously isolated from dolphin or killer whale blowholes (Corynebacteria, others). Many examples of exogenous marine species were identified, including Tenacibaculum and Psychrobacter spp. that have been associated with the skin microbiota of marine mammals and fish and may include pathogens. This information provides a baseline of respiratory tract microbiota profiles of contemporary whale health. Customized UAVs are a promising new tool for marine megafauna research and may have broad application in cost-effective monitoring and management of whale populations worldwide.

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Responses of bottlenose dolphins (Tursiops spp.) to small drones

Giles

Butcher

Colefax

et al. 2020

Aquatic Conservation

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Recent advances in aerial drones offer new insights into the biology, ecology and behaviour of marine wildlife found on or near the ocean’s surface. While opening up new opportunities for enhanced wildlife monitoring, the impacts of drone sampling and how it might influence interpretations of animal behaviour are only just beginning to be understood. The capacity of drones to record bottlenose dolphin (Tursiops spp.) behaviour was investigated, along with how the presence of a small drone at varying altitudes influences dolphin behaviour. Over 3 years and eight locations, 361 drone flights were completed between altitudes of 5 and 60 m above the ocean. Analyses showed that dolphins were increasingly likely to change behaviour with decreasing drone altitude. A positive correlation was also found between time spent hovering above a group of dolphins and the probability of recording a behavioural response. Dolphin group size also influenced the frequency of an observed behavioural change, displaying a positive correlation between behaviour change and group size. Overall, although drones have the potential to impact coastal dolphins when flown at low altitudes, they represent a useful tool for collecting ecological information on coastal dolphins owing to their convenience, low cost and capacity to observe behaviours underwater. To maximize benefits and minimize impacts, this study suggests that drones should be flown 30 m above coastal bottlenose dolphins.

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A small unmanned aerial system for estimating abundance and size of Antarctic predators

Cited by 174 publications

References 37 publications

The Use of Unmanned Aerial Systems in Marine Mammal Research

The Use of Unmanned Aerial Systems in Marine Mammal Research

An Economical Custom-Built Drone for Assessing Whale Health

Responses of bottlenose dolphins (Tursiops spp.) to small drones

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