A cellular automaton for the factor of safety field in landslides modeling

Piegari, E.; Cataudella, V.; Maio, Rosa Di; Milano, L.; Nicodemi, Mario

doi:10.1029/2005gl024759

Cited by 34 publications

(33 citation statements)

References 27 publications

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“…2a, for a small value of ν, p(τ ) exhibits a linear regime in a log-log scale -that means a power-law regime in a linear scale -for recurrence time intervals that enlarge by increasing the threshold q. We note that in the limit of small values of ν, the model resembles the results of the OFC model (Olami et al, 1992), as extensively discussed in previous works (Piegari et al, 2006a(Piegari et al, , 2009a. Thus, in this regime p(τ ) is expected to be characterized by a power-law regime according to SOC-like models proposed for explaining recurrence time statistics of earthquakes and solar flares (Sanchez et al, 2002;Corral, 2004;Pacuzski et al, 2005).…”

Section: Analysis Of Varying Threshold Valuessupporting

confidence: 74%

“…In other words, we take into account non-conservative (dissipative) cases where the quantity C = nn f nn , which fixes the degree of conservation of the system, is less than 1, contrary to other approaches (Hergarten and Neugebauer, 2000;Hergarten, 2003). The role of the model parameter C has been investigated in previous works, where we found that the shape of the frequencysize probability distribution of landslide events is strongly affected by the values of C (Piegari et al, 2006a), while it is not significantly affected by the values of the coefficients f nn in the range of values that supply power-law distributions (Piegari et al, 2006b). In particular, only if C < 1 do our synthetic frequency-size distributions reproduce those from catalogues (Piegari et al, 2009a), pointing out the relevance of dissipative phenomena to landslide triggering.…”

Section: The Modelmentioning

confidence: 99%

“…In this paper, we analyse the recurrence time statistics of a cellular automaton (CA) model aimed at reproducing the main features of landslide event statistics by means of some characteristic parameters (Piegari et al, 2006a(Piegari et al, , 2009a.…”

Section: Introductionmentioning

confidence: 99%

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Recurrence time distribution and temporal clustering properties of a cellular automaton modelling landslide events

Piegari

Maio

Avella

2013

Nonlin. Processes Geophys.

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Abstract. Reasonable prediction of landslide occurrences in a given area requires the choice of an appropriate probability distribution of recurrence time intervals. Although landslides are widespread and frequent in many parts of the world, complete databases of landslide occurrences over large periods are missing and often such natural disasters are treated as processes uncorrelated in time and, therefore, Poisson distributed. In this paper, we examine the recurrence time statistics of landslide events simulated by a cellular automaton model that reproduces well the actual frequency-size statistics of landslide catalogues. The complex time series are analysed by varying both the threshold above which the time between events is recorded and the values of the key model parameters. The synthetic recurrence time probability distribution is shown to be strongly dependent on the rate at which instability is approached, providing a smooth crossover from a power-law regime to a Weibull regime. Moreover, a Fano factor analysis shows a clear indication of different degrees of correlation in landslide time series. Such a finding supports, at least in part, a recent analysis performed for the first time of an historical landslide time series over a time window of fifty years.

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Section: Analysis Of Varying Threshold Valuessupporting

confidence: 74%

Section: The Modelmentioning

confidence: 99%

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Recurrence time distribution and temporal clustering properties of a cellular automaton modelling landslide events

Piegari

Maio

Avella

2013

Nonlin. Processes Geophys.

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“…Lübeck (1997) conducted large-scale simulations of a similar Zhang sandpile and obtained exponents slightly higher than 1.2, which can go even higher for large driving rates ν. In a similar model that incorporated non-conservation, Piegari et al (2006) obtained power-law exponents that approach 1.6 in the conservative limit for the same order or magnitude of ν that we used. The higher exponents and the effect of the driving rates are also verified by an equivalent conservative model and actual sand avalanche experiments by Juanico et al (2008), and in other asynchronous updating models (Paguirigan et al, 2015).…”

Section: Model Specificationsmentioning

confidence: 99%

“…The sandpile model, introduced as a representative system for illustrating self-organized criticality (SOC; Bak et al, 1987), has opened up new avenues for the use of discrete cellular automata (CA) models in capturing the salient features of many systems in nature (Olami et al, 1992;Drossel and Schwabl, 1992;Malamud and Turcotte, 2000;Piegari et al, 2006;Juanico et al, 2008). Seismicity, which is rife with power-law statistical distributions (Saichev and Sornette, 2006), is an interesting test case for such approaches.…”

Section: Introductionmentioning

confidence: 99%

Sandpile-based model for capturing magnitude distributions and spatiotemporal clustering and separation in regional earthquakes

Batac

Paguirigan

Tarun

et al. 2017

Nonlin. Processes Geophys.

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Abstract. We propose a cellular automata model for earthquake occurrences patterned after the sandpile model of selforganized criticality (SOC). By incorporating a single parameter describing the probability to target the most susceptible site, the model successfully reproduces the statistical signatures of seismicity. The energy distributions closely follow power-law probability density functions (PDFs) with a scaling exponent of around − 1.6, consistent with the expectations of the Gutenberg-Richter (GR) law, for a wide range of the targeted triggering probability values. Additionally, for targeted triggering probabilities within the range 0.004-0.007, we observe spatiotemporal distributions that show bimodal behavior, which is not observed previously for the original sandpile. For this critical range of values for the probability, model statistics show remarkable comparison with long-period empirical data from earthquakes from different seismogenic regions. The proposed model has key advantages, the foremost of which is the fact that it simultaneously captures the energy, space, and time statistics of earthquakes by just introducing a single parameter, while introducing minimal parameters in the simple rules of the sandpile. We believe that the critical targeting probability parameterizes the memory that is inherently present in earthquakegenerating regions.

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A multidimensional stability model for predicting shallow landslide size and shape across landscapes

et al. 2014

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The size of a shallow landslide is a fundamental control on both its hazard and geomorphic importance. Existing models are either unable to predict landslide size or are computationally intensive such that they cannot practically be applied across landscapes. We derive a model appropriate for natural slopes that is capable of predicting shallow landslide size but simple enough to be applied over entire watersheds. It accounts for lateral resistance by representing the forces acting on each margin of potential landslides using earth pressure theory and by representing root reinforcement as an exponential function of soil depth. We test our model's ability to predict failure of an observed landslide where the relevant parameters are well constrained by field data. The model predicts failure for the observed scar geometry and finds that larger or smaller conformal shapes are more stable. Numerical experiments demonstrate that friction on the boundaries of a potential landslide increases considerably the magnitude of lateral reinforcement, relative to that due to root cohesion alone. We find that there is a critical depth in both cohesive and cohesionless soils, resulting in a minimum size for failure, which is consistent with observed size-frequency distributions. Furthermore, the differential resistance on the boundaries of a potential landslide is responsible for a critical landslide shape which is longer than it is wide, consistent with observed aspect ratios. Finally, our results show that minimum size increases as approximately the square of failure surface depth, consistent with observed landslide depth-area data.

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A cellular automaton for the factor of safety field in landslides modeling

Cited by 34 publications

References 27 publications

Recurrence time distribution and temporal clustering properties of a cellular automaton modelling landslide events

Recurrence time distribution and temporal clustering properties of a cellular automaton modelling landslide events

Sandpile-based model for capturing magnitude distributions and spatiotemporal clustering and separation in regional earthquakes

A multidimensional stability model for predicting shallow landslide size and shape across landscapes

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