On the scaling of activity in tropical forest mammals

Cid, Bruno; Carbone, Chris; Fernandez, Fernando A. S.; Jansen, Patrick A.; Rowcliffe, J. Marcus; O’Brien, Timothy G.; Akampurira, Emmanuel; Bitariho, Robert; Espinosa, Santiago; Gajapersad, Krishna; Santos, Thiago Mateus Rocha dos; Gonçalves, André Luís Sousa; Kinnaird, Margaret F.; Lima, Marcela Guimarães Moreira; Martin, Emanuel H.; Mugerwa, Badru; Rovero, Francesco; Salvador, Julia; Santos, Fernanda; Spironello, Wilson Roberto; Wijntuin, Soraya; Oliveira‐Santos, Luiz Gustavo Rodrigues

doi:10.1111/oik.07022

Cited by 12 publications

(31 citation statements)

References 70 publications

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“…Based on this systematic year-long camera-trap study, we found little support for diel activity levels to scale significantly and positively with body mass, or to differ between ruminants and nonruminants, or between herbivores and faunivores. For herbivores, the absence of a body mass scaling resembles the recent finding of Cid et al (2020).…”

Section: Discussionsupporting

confidence: 72%

“…In these species, terrestrial camera-trap placement may not represent their entire habitat niche and may thus result in biased activity patterns. In addition, our activity analyses are based on the sampled population of a species and did not differentiate between individual-level or sex-specific diel activity patterns, which F I G U R E 3 Relationship of activity levels and body mass from this study as compared to data obtained from 249 populations of terrestrial mammals in the tropics (Cid et al, 2020), distinguished as carnivores, herbivores, insectivores, and omnivores. Note the general overlap of data, that a scaling in herbivores may depend critically on including species smaller than available in the present study, and that the scaling in carnivores may depend critically on whether invertebrate and vertebrate prey are considered different trophic niches or not.…”

Section: Methodological Aspects Of Camera Trapping and Activity Recordingmentioning

confidence: 93%

“…Gray-shaded areas represent night time, defined by the average time of sunrise and sunset during the study period ("catchability"), and quality of food are particularly variable in faunivores (Carbone et al, 2007). Comparative studies are further complicated by the fact that sometimes, invertebrate feeding is included in the category of "carnivory" (Carbone et al, 1999), and sometimes insectivory and carnivory are clearly distinguished (Cid et al, 2020).…”

Section: Notementioning

confidence: 99%

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Camera‐trap data do not indicate scaling of diel activity and cathemerality with body mass in an East African mammal assemblage

Clauss

Scriba

Kioko

et al. 2021

Ecology and Evolution

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Diel activity patterns, that is, the times when animals are active over the course of the day (e.g., circadian rhythms) and how much they are active over the course of the day (activity level), are fundamental aspects of animal behavior (Daan & Aschoff, 2001;Halberg, 1960).How animals distribute their diel activity and the duration of time during which they are active during the day largely reflect their interactions with food resources, potential mates, predators, and competitors. In their evolutionary histories, mammalian faunivores have generally shifted toward nocturnality and mammalian herbivores toward diurnality (Wu et al., 2018).Diel activity patterns of animals can be classified into diurnal, nocturnal, crepuscular, or cathemeral (Bennie et al., 2014), and the quantitative information on which these categories are based can be gained from camera-trap data (Rowcliffe et al., 2014). Although

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Section: Discussionsupporting

confidence: 72%

Section: Methodological Aspects Of Camera Trapping and Activity Recordingmentioning

confidence: 93%

Section: Notementioning

confidence: 99%

See 1 more Smart Citation

Camera‐trap data do not indicate scaling of diel activity and cathemerality with body mass in an East African mammal assemblage

Clauss

Scriba

Kioko

et al. 2021

Ecology and Evolution

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“…This is consistent with other findings concerning foraging space use: large‐bodied birds, which tend to feed on high‐quality resources and forage over large spatial scales (Schoener 1968), travel farther in homogeneous environments than heterogeneous environments (Tucker et al 2019). Among mammals, trophic level is correlated with home range size (Jetz et al 2004), which is positively correlated with activity levels (Cid et al 2020), suggesting a positive relationship between space use and activity levels over large scales.…”

Section: Discussionmentioning

confidence: 99%

“…These interact when animals forage, as they need to traverse the landscape according to their movement capacities to locate resources distributed non‐randomly in the environment (Suryan et al 2008). To maximize energetic gains from foraging, the timing of an animal's foraging movements is expected to correspond to either the temporal availability of its resources (Rydell et al 1996, Lang et al 2018) or the quantity and quality of resources required (Jetz et al 2004, Ramesh et al 2015, Cid et al 2020). Alternatively, animals can reduce their energy expenditure by timing their foraging activity when their movements are most energetically efficient (Chapman et al 2011, Shepard et al 2013) via behavioral thermoregulation (Matern et al 2000) and passive movement (Krupczynski and Schuster 2008).…”

Section: Introductionmentioning

confidence: 99%

Diurnal timing of nonmigratory movement by birds: the importance of foraging spatial scales

Mallon

Tucker

Beard

et al. 2020

Journal of Avian Biology

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Timing of activity can reveal an organism's efforts to optimize foraging either by minimizing energy loss through passive movement or by maximizing energetic gain through foraging. Here, we assess whether signals of either of these strategies are detectable in the timing of activity of daily, local movements by birds. We compare the similarities of timing of movement activity among species using six temporal variables: start of activity relative to sunrise, end of activity relative to sunset, relative speed at midday, number of movement bouts, bout duration and proportion of active daytime hours. We test for the influence of flight mode and foraging habitat on the timing of movement activity across avian guilds. We used 64 570 days of GPS movement data collected between 2002 and 2019 for local (non-migratory) movements of 991 birds from 49 species, representing 14 orders. Dissimilarity among daily activity patterns was best explained by flight mode. Terrestrial soaring birds began activity later and stopped activity earlier than pelagic soaring or flapping birds. Broad-scale foraging habitat explained less of the clustering patterns because of divergent timing of active periods of pelagic surface and diving foragers. Among pelagic birds, surface foragers were active throughout all 24 hrs of the day while diving foragers matched their active hours more closely to daylight hours. Pelagic surface foragers also had the greatest daily foraging distances, which was consistent with their daytime activity patterns. This study demonstrates that flight mode and foraging habitat influence temporal patterns of daily movement activity of birds.

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Inter‐population variability in movement parameters: practical implications for population density estimation

et al. 2023

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Motion‐sensitive cameras are popular as non‐invasive monitoring tools, and several methods have been developed to estimate population densities from camera data. These methods frequently rely on auxiliary movement data including the distance traveled by an individual in a day and the proportion of the day that an animal spends moving when individual recognition is not possible. The estimation of these movement parameters is time‐consuming, which could limit the applicability of cameras to estimate population density. To investigate the relevance of measuring movement parameters for the target population, we monitored 54 wildlife populations of red deer (Cervus elaphus), fallow deer (Dama dama), roe deer (Capreolus capreolus), wild boar (Sus scrofa), and red fox (Vulpes vulpes) in different seasons through Europe with cameras. We estimated 91‐day ranges and activity levels. We fitted mixed models for day range and activity level as response variables to assess if the inter‐population variability in movement was explained by a set of a priori relevant geographical, environmental, biological, and management predictors. We then explored the bias in density estimates obtained in 25 independent populations when using predicted movement data. There was high intra‐species variation in day range and activity level among species and populations. Only species explained a small proportion of this variability; other predictor variables did not. We observed bias in densities when predicting the day range and activity for independent populations. Considering the intra‐species variability in movement parameters and the consequent unacceptable bias in density estimates, we recommend that monitoring and conservation programs estimate movement parameters for the target population and survey populations from camera data for more accurate density estimates. While this increases the handling time needed to estimate densities, it is worth the cost because of the reliability of camera‐based methodologies to estimate needed movement parameters.

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On the scaling of activity in tropical forest mammals

Cited by 12 publications

References 70 publications

Camera‐trap data do not indicate scaling of diel activity and cathemerality with body mass in an East African mammal assemblage

Camera‐trap data do not indicate scaling of diel activity and cathemerality with body mass in an East African mammal assemblage

Diurnal timing of nonmigratory movement by birds: the importance of foraging spatial scales

Inter‐population variability in movement parameters: practical implications for population density estimation

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