Time Dependent Diffusion as a Mean Field Counterpart of Lévy Type Random Walk

Ahmed, Danish A.; Petrovskii, Sergei

doi:10.1051/mmnp/201510202

Cited by 15 publications

(28 citation statements)

References 66 publications

(107 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…What is an appropriate choice of D(t) is a subtle issue [2] and will be considered in detail elsewhere [3]. Here we only consider two tentative examples:…”

Section: Trapping Of Levy-walking Insects: Time-dependent Diffusion Amentioning

confidence: 99%

See 1 more Smart Citation

Multiscale approach to pest insect monitoring: Random walks, pattern formation, synchronization, and networks

Petrovskii

Petrovskaya

Bearup

2014

Physics of Life Reviews

104

View full text Add to dashboard Cite

Pest insects pose a significant threat to food production worldwide resulting in annual losses worth hundreds of billions of dollars. Pest control attempts to prevent pest outbreaks that could otherwise destroy a sward. It is good practice in integrated pest management to recommend control actions (usually pesticides application) only when the pest density exceeds a certain threshold. Accurate estimation of pest population density in ecosystems, especially in agro-ecosystems, is therefore very important, and this is the overall goal of the pest insect monitoring. However, this is a complex and challenging task; providing accurate information about pest abundance is hardly possible without taking into account the complexity of ecosystems' dynamics, in particular, the existence of multiple scales. In the case of pest insects, monitoring has three different spatial scales, each of them having their own scale-specific goal and their own approaches to data collection and interpretation. In this paper, we review recent progress in mathematical models and methods applied at each of these scales and show how it helps to improve the accuracy and robustness of pest population density estimation.

show abstract

“…What is an appropriate choice of D(t) is a subtle issue [2] and will be considered in detail elsewhere [3]. Here we only consider two tentative examples:…”

Section: Trapping Of Levy-walking Insects: Time-dependent Diffusion Amentioning

confidence: 99%

“…Let us consider the single-trap scale of the pest monitoring problem. In this section, we show that, even in case of a genuine Levy walk, the problem of trap counts interpretation can still be addressed based on the diffusion equation [2,3].…”

Section: Trapping Of Levy-walking Insects: Time-dependent Diffusion Amentioning

confidence: 99%

Multiscale approach to pest insect monitoring: Random walks, pattern formation, synchronization, and networks

Petrovskii

Petrovskaya

Bearup

2014

Physics of Life Reviews

104

View full text Add to dashboard Cite

show abstract

“…In the context of insect pest monitoring, diffusion models have shown to provide a good theoretical framework and the means for trap count interpretation [12,27,35]. In particular, time dependent diffusion provides an adequate description for more complicated behaviour, at least where standard diffusion fails [26,27,35,64]. The notion of insect movement with time dependent diffusivity is not new, and has been observed in field studies [19].…”

Section: Time Dependent Diffusionmentioning

confidence: 99%

“…Obviously, the issue becomes more difficult if a combination of these features are present. In the context of insect pest monitoring, diffusion models have shown to provide a good theoretical framework and the means for trap count interpretation [12,27,35]. In particular, time dependent diffusion provides an adequate description for more complicated behaviour, at least where standard diffusion fails [26,27,35,64].…”

Section: Time Dependent Diffusionmentioning

confidence: 99%

“…Traps are usually installed in the field under controlled experimental conditions as a means to estimate population abundance [13][14][15]. They are then exposed for the duration of study, insects are caught, traps are normally emptied at regular intervals and the total number which fall into the trap Petrovskii [27]. Our aim is two-fold; that is to propose a diffusion model which consists of parameters that are of ecological significance and can be interpreted with reference to the diffusive properties.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The “Lévy or Diffusion” Controversy: How Important is the Movement Pattern in the Context of Trapping?

Ahmed¹,

Petrovskii²,

Tilles³

2018

Preprint

View full text Add to dashboard Cite

Many empirical and theoretical studies indicate that Brownian motion and diffusion models as its mean field counterpart provide appropriate modelling techniques for individual insect movement. However, this traditional approach has been challenged and conflicting evidence suggests that an alternative movement pattern such as Lévy walks can provide a better description. Lévy walks differ from Brownian motion since they allow for a higher frequency of large steps, resulting in a faster movement. Identification of the 'correct' movement model that would consistently provide the best fit for movement data is challenging and has become a highly controversial issue. In this paper, we show that this controversy may be superficial rather than real if the issue is considered in the context of trapping or, more generally, survival probabilities. In particular, we show that almost identical trap counts are reproduced for inherently different movement models (such as the Brownian motion and the Lévy walk) under certain conditions of equivalence. This apparently suggests that the whole 'Levy or diffusion' debate is rather senseless unless it is placed into a specific ecological context, e.g. pest monitoring programmes.

show abstract

Three-dimensional random walk models of individual animal movement and their application to trap counts modelling

Ahmed

Benhamou

Bonsall

et al. 2021

Journal of Theoretical Biology

View full text Add to dashboard Cite

Time Dependent Diffusion as a Mean Field Counterpart of Lévy Type Random Walk

Cited by 15 publications

References 66 publications

Multiscale approach to pest insect monitoring: Random walks, pattern formation, synchronization, and networks

Multiscale approach to pest insect monitoring: Random walks, pattern formation, synchronization, and networks

The “Lévy or Diffusion” Controversy: How Important is the Movement Pattern in the Context of Trapping?

Three-dimensional random walk models of individual animal movement and their application to trap counts modelling

Contact Info

Product

Resources

About

Time Dependent Diffusion as a Mean Field Counterpart of Lévy Type Random Walk

Cited by 15 publications

References 66 publications

Multiscale approach to pest insect monitoring: Random walks, pattern formation, synchronization, and networks

Multiscale approach to pest insect monitoring: Random walks, pattern formation, synchronization, and networks

The &ldquo;L&eacute;vy or Diffusion&rdquo; Controversy: How Important is the Movement Pattern in the Context of Trapping?

Three-dimensional random walk models of individual animal movement and their application to trap counts modelling

Contact Info

Product

Resources

About

The “Lévy or Diffusion” Controversy: How Important is the Movement Pattern in the Context of Trapping?