Restricted Gompertz-Type Diffusion Processes with Periodic Regulation Functions

Giorno, Virginia; Nobile, Amelia Giuseppina

doi:10.3390/math7060555

Cited by 10 publications

(10 citation statements)

References 35 publications

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“…Taking into account the various behaviours that the curve N GP D (t) may have for different choices of a, we are interested in a generic threshold S > y if the curve grows to infinity, or on a percentage p of the carrying capacity C = ye Ab , or on a percentage of the size of the population at the inflection point t I given in (15). For a generic S, to obtain the crossing time instant θ S of N GP D (t) through S, we solve the equation N (θ S ) = S, recalling (11).…”

Section: Threshold Crossingmentioning

confidence: 99%

“…In this framework, stochastic processes for the modeling of real growth phenomena have been largely considered in the literature. We recall the well-known approach based on diffusion processes for the stochastic model of tumor growth, such as that exploited in Albano and Giorno [1], Giorno et al [17], Giorno and Nobile [15], Hanson and Tier [19], Spina et al [29]. Other studies including Gompertz and logistic growth models based on stochastic diffusions can be found in Campillo et al [8], Himadri Ghosh and Prajneshu [21], and Yoshioka et al [36].…”

Section: Introductionmentioning

confidence: 99%

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A generalized Gompertz growth model with applications and related birth-death processes

Asadi

Crescenzo

Sajadi

et al. 2020

Preprint

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In this paper, we propose a flexible growth model that constitutes a suitable generalization of the well-known Gompertz model. We perform an analysis of various features of interest, including a sensitivity analysis of the initial value and the three parameters of the model. We show that the considered model provides a good fit to some real datasets concerning the growth of the number of individuals infected during the COVID-19 outbreak, and software failure data. The goodness of fit is established on the ground of the ISRP metric and the $d_2$-distance. We also analyze two time-inhomogeneous stochastic processes, namely a birth-death process and a birth process, whose means are equal to the proposed growth curve. In the first case we obtain the probability of ultimate extinction, being 0 an absorbing endpoint. We also deal with a threshold crossing problem both for the proposed growth curve and the corresponding birth process.

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Section: Threshold Crossingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A generalized Gompertz growth model with applications and related birth-death processes

Asadi

Crescenzo

Sajadi

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…2, when Ab > a + 1. We consider the maximum specific growth rate, say μ, which is the coefficient of the tangent to the curve N G P D (t) given in (12) in the inflection point t I shown in (16): Moreover, recalling the expressions of t I and N G P D (t I ), the tangent to the curve…”

Section: The Maximum Specific Growth Rate and The Lag Timementioning

confidence: 99%

“…We are interested in the time instant in which N (t) reaches S, with S > N (0) = y. Taking into account the various behaviours that the curve N G P D (t) may have for different choices of a, we are interested in a generic threshold S > y if the curve grows to infinity, or on a percentage p of the carrying capacity C = ye Ab , or on a percentage of the size of the population at the inflection point t I given in (16). For a generic S, to obtain the crossing time instant θ S of N G P D (t) through S, we solve the equation N (θ S ) = S, recalling (12).…”

Section: Threshold Crossingmentioning

confidence: 99%

A generalized Gompertz growth model with applications and related birth-death processes

et al. 2020

View full text Add to dashboard Cite

In this paper, we propose a flexible growth model that constitutes a suitable generalization of the well-known Gompertz model. We perform an analysis of various features of interest, including a sensitivity analysis of the initial value and the three parameters of the model. We show that the considered model provides a good fit to some real datasets concerning the growth of the number of individuals infected during the COVID-19 outbreak, and software failure data. The goodness of fit is established on the ground of the ISRP metric and the $$d_2$$ d 2 -distance. We also analyze two time-inhomogeneous stochastic processes, namely a birth-death process and a birth process, whose means are equal to the proposed growth curve. In the first case we obtain the probability of ultimate extinction, being 0 an absorbing endpoint. We also deal with a threshold crossing problem both for the proposed growth curve and the corresponding birth process. A simulation procedure for the latter process is also exploited.

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“…With respect to the Kolmogorov equations, it was defined by Nafidi [18], in a general way and for both the univariate and the multivariate cases. In various papers, Gutiérrez et al [19-21], Ferrante et al [22], Román-Román et al [23] and Giorno and Nobile [24], have highlighted the importance of this process, and many subsequent extensions have appeared, especially regarding the non-homogeneous case with exogenous factors (external variables) that affect the drift coefficient. In general, these extensions take one of the following two forms:With external information (when no functional form is available): the exogenous factors are completely determined by the observed data (monthly, annual, etc.)…”

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confidence: 99%

Powers of the Stochastic Gompertz and Lognormal Diffusion Processes, Statistical Inference and Simulation

2020

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In this paper, we study a new family of Gompertz processes, defined by the power of the homogeneous Gompertz diffusion process, which we term the powers of the stochastic Gompertz diffusion process. First, we show that this homogenous Gompertz diffusion process is stable, by power transformation, and determine the probabilistic characteristics of the process, i.e., its analytic expression, the transition probability density function and the trend functions. We then study the statistical inference in this process. The parameters present in the model are studied by using the maximum likelihood estimation method, based on discrete sampling, thus obtaining the expression of the likelihood estimators and their ergodic properties. We then obtain the power process of the stochastic lognormal diffusion as the limit of the Gompertz process being studied and go on to obtain all the probabilistic characteristics and the statistical inference. Finally, the proposed model is applied to simulated data. both in the homogeneous and in the non-homogeneous cases and many particular SDP have been proposed, such as Katsamaki and Skiadas [11] in the case of the exponential model, Skiadas and Giovanis [12] in the case of the Bass model, Giovanis and Skiadas [13] in the case of the logistic model, Gutiérrez et al. [14] in the case of the Rayleigh model and in the case of the lognormal with exogenous factors.Among the above-mentioned processes is the Stochastic Gompertz Diffusion Process (SGDP), which was first proposed by Ricciardi [16], who defined it in the homogeneous case by means of stochastic differential equations, for use in studies of population growth. It was subsequently used by Dennis and Patil [17] in ecology modelling. With respect to the Kolmogorov equations, it was defined by Nafidi [18], in a general way and for both the univariate and the multivariate cases. In various papers, Gutiérrez et al. [19-21], Ferrante et al. [22], Román-Román et al. [23] and Giorno and Nobile [24], have highlighted the importance of this process, and many subsequent extensions have appeared, especially regarding the non-homogeneous case with exogenous factors (external variables) that affect the drift coefficient. In general, these extensions take one of the following two forms:With external information (when no functional form is available): the exogenous factors are completely determined by the observed data (monthly, annual, etc.) and to obtain their functional forms interpolation methods, among others, can be used. This methodology has been applied by Gutiérrez et al. [25,26], Rupsys et al. [27] and Badurally Adam et al. [28]. In all these papers it is assumed that the coefficient drift is a linear combination of exogenous factors, obtained by linear interpolation.Without external information: in this case there are no observed data for the exogenous factors, but they are functions of time and of certain parameters. For example, the case in which the deceleration factor is affected by exogenous factors was developed by Gutiérrez et a...

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Restricted Gompertz-Type Diffusion Processes with Periodic Regulation Functions

Cited by 10 publications

References 35 publications

A generalized Gompertz growth model with applications and related birth-death processes

A generalized Gompertz growth model with applications and related birth-death processes

A generalized Gompertz growth model with applications and related birth-death processes

Powers of the Stochastic Gompertz and Lognormal Diffusion Processes, Statistical Inference and Simulation

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Restricted Gompertz-Type Diffusion Processes with Periodic Regulation Functions

Cited by 10 publications

References 35 publications

A generalized Gompertz growth model with applications&nbsp;and related birth-death processes

A generalized Gompertz growth model with applications&nbsp;and related birth-death processes

A generalized Gompertz growth model with applications and related birth-death processes

Powers of the Stochastic Gompertz and Lognormal Diffusion Processes, Statistical Inference and Simulation

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A generalized Gompertz growth model with applications and related birth-death processes

A generalized Gompertz growth model with applications and related birth-death processes