Fitting functional response surfaces to data: a best practice guide

Uszko, Wojciech; Diehl, Sebastian; Wickman, Jonas

doi:10.1002/ecs2.3051

Cited by 29 publications

(58 citation statements)

References 49 publications

(57 reference statements)

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“…how many and how large a range of species abundance levels are employed; Sarnelle &Wilson (2008); Uszko et al . (2020)), observer error in estimating species densities and the number of eaten prey (Jost and Arditi, 2000), and the behavioural variation that exists among consumer and prey individuals (Chesson, 1984; Abrams, 2010). Many such sources of variation will be present even in the well‐controlled laboratory studies that dominate the literature, and could even be magnified in such studies given the small numbers of individual animals that are typically involved at low‐abundance treatment levels (Coblentz, 2020; Novak et al ., 2017).…”

Section: Discussionmentioning

confidence: 99%

“…This will occur directly via the bias inherent in their own maximum‐likelihood estimators (Box 2), and indirectly through their functional relationships and data‐dependent covariances with the estimates of other biased parameters. For example, bias is also expected for the attack rate parameter with which the interference parameter is functionally intertwined in the Arditi–Akçakaya model (see also Gutenkunst et al ., 2007; Uszko et al ., 2020), or for any deterministic functional‐response parameter when the assumed likelihood model entails `nuisance’ parameters whose estimates are biased (e.g. the standard deviation of the Gaussian likelihood; see Supplementary Materials ).…”

Section: Discussionmentioning

confidence: 99%

“…the standard deviation of the Gaussian likelihood; see Supplementary Materials ). Even for the simple Holling Type II model, estimates of the attack rate and handling time parameters can exhibit significant covariation (Papanikolaou et al ., 2016; Uszko et al ., 2020). The effect of covariation on bias will be especially large when feeding rate variation is large and heteroskedastic, or when the range over which species abundances are varied is insufficient to constrain estimates.…”

Section: Discussionmentioning

confidence: 99%

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Systematic bias in studies of consumer functional responses

Novák

Stouffer

2020

Ecology Letters

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Functional responses are a cornerstone to our understanding of consumer–resource interactions, so how to best describe them using models has been actively debated. Here we focus on the consumer dependence of functional responses to evidence systematic bias in the statistical comparison of functional‐response models and the estimation of their parameters. Both forms of bias are universal to nonlinear models (irrespective of consumer dependence) and are rooted in a lack of sufficient replication. Using a large compilation of published datasets, we show that – due to the prevalence of low sample size studies – neither the overall frequency by which alternative models achieve top rank nor the frequency distribution of parameter point estimates should be treated as providing insight into the general form or central tendency of consumer interference. We call for renewed clarity in the varied purposes that motivate the study of functional responses, purposes that can compete with each other in dictating the design, analysis and interpretation of functional‐response experiments.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Systematic bias in studies of consumer functional responses

Novák

Stouffer

2020

Ecology Letters

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“…More specifically, both model-comparison bias (Box 1) and parameter-estimation bias (Box 2) are a function of a focal model’s parametric and geometric complexity, how well these are estimated, and for consumer functional responses, how these interact with the feeding rate variation within and among the treatment levels of an experiment. Sources of variation will include experimental design (e.g., how many and how large a range of species abundance levels are employed; Sarnelle & Wilson (2008); Uszko et al (2020)), observer error in estimating species densities and the number of eaten prey (Jost & Arditi, 2000), and the behavioural variation that exists among consumer and prey individuals (Abrams, 2010; Chesson, 1984). Many such sources of variation will be present even in the well-controlled laboratory studies that dominate the literature, and could even be magnified in such studies given the small numbers of individual animals that are typically involved at low-abundance treatment levels (Coblentz & DeLong, 2020; Novak et al , 2017).…”

Section: Discussionmentioning

confidence: 99%

Systematic bias in studies of consumer functional responses

Novák

Stouffer

2020

Preprint

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Functional responses are a cornerstone to our understanding of consumer-resource interactions, so how to best describe them using models has been actively debated. Here we focus on the consumer dependence of functional responses to evidence systematic bias in the statistical comparison of functional-response models and the estimation of their parameters. Both forms of bias are universal to nonlinear models (irrespective of consumer dependence) and are rooted in a lack of sufficient replication. Using a large compilation of published datasets, we show that – due to the prevalence of low sample size studies – neither the overall frequency by which alternative models achieve top rank nor the frequency distribution of parameter point estimates should be treated as providing insight into the general form or central tendency of consumer interference. We call for renewed clarity in the varied purposes that motivate the study of functional responses, purposes that can compete with each other in dictating the design, analysis and interpretation of functional-response experiments.

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“…This is repeated across all the prey densities multiple times typically using different predator individuals for each trial. The experimenters then fit a functional response model (or models) to the data using one of several existing statistical methods depending on whether prey were replaced as they were eaten (Royama, 1971;Rogers, 1972;Bolker, 2008;Rosenbaum & Rall, 2018;Uszko, Diehl, & Wickman, 2020).…”

Section: Introductionmentioning

confidence: 99%

Estimating predator functional responses using the times between prey captures

Coblentz

DeLong

2020

Preprint

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Predator functional responses, which describe how predator feeding rates change with prey densities, are a core component of predator-prey theory. Given their importance, ecologists have measured thousands of predator functional responses. However, most of these studies have used a single standard experimental method that is ill-suited to address many current, pressing questions regarding functional responses.We derive a new experimental design and statistical analysis that quantifies the parameters of predator functional responses by using the time between a predator’s feeding events and can be used with individual predators requiring only one or a few trials. We examine the feasibility of this experimental method and analysis by using simulations to examine the ability of the statistical model to estimate the ‘true’ functional response parameters from simulated data. We also perform a proof-of-concept experiment estimating the functional responses of two individual jumping spiders feeding on midges.Our simulations show that the statistical method is capable of reliably estimating functional response parameters under a wide range of parameter values and sample sizes. Our proof-of-concept experiment illustrates that the experimental design and statistical method provided reasonable estimates of functional response parameters and good fits to the data for individual jumping spiders using only a few trials per individual.By virtue of the fewer number of trials required to measure a functional response, the method derived here promises to expand the questions that can be addressed using functional response experiments and the systems for which functional responses can be measured. For example, this method is well-poised to address questions such as intraspecific variation in predator functional response parameters and the role of predator and prey traits and abiotic conditions on shaping functional responses. We hope, therefore, that this time-between-captures method will refine our understanding of functional responses and thereby our understanding of predator-prey interactions more generally.

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Fitting functional response surfaces to data: a best practice guide

Cited by 29 publications

References 49 publications

Systematic bias in studies of consumer functional responses

Systematic bias in studies of consumer functional responses

Systematic bias in studies of consumer functional responses

Estimating predator functional responses using the times between prey captures

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