The effects of random and seasonal environmental fluctuations on optimal harvesting and stocking

We analyze the harvesting and stocking of a population that is affected by random and seasonal environmental fluctuations. The main novelty comes from having three layers of environmental fluctuations. The first layer is due to the environment switching at random times between different environmental states. This is similar to having sudden environmental changes or catastrophes. The second layer is due to seasonal variation, where there is a significant change in the dynamics between seasons. Finally, the third layer is due to the constant presence of environmental stochasticity—between the seasonal or random regime switches, the species is affected by fluctuations which can be modelled by white noise. This framework is more realistic because it can capture both significant random and deterministic environmental shifts as well as small and frequent fluctuations in abiotic factors. Our framework also allows for the price or cost of harvesting to change deterministically and stochastically, something that is more realistic from an economic point of view. The combined effects of seasonal and random fluctuations make it impossible to find the optimal harvesting-stocking strategy analytically. We get around this roadblock by developing rigorous numerical approximations and proving that they converge to the optimal harvesting-stocking strategy. We apply our methods to multiple population models and explore how prices, or costs, and environmental fluctuations influence the optimal harvestingstocking strategy. We show that in many situations the optimal way of harvesting and stocking is not of threshold type.

[1]  Alexandru Hening,et al.  Optimal sustainable harvesting of populations in random environments , 2018, Stochastic Processes and their Applications.

[2]  Erkki Koskela,et al.  Optimal Harvesting Under Resource Stock and Price Uncertainty , 2005, SSRN Electronic Journal.

[3]  Sebastian J. Schreiber,et al.  Protected polymorphisms and evolutionary stability of patch-selection strategies in stochastic environments , 2014, bioRxiv.

[4]  Kristian R. Miltersen,et al.  Commodity price modelling that matches current observables: a new approach , 2003 .

[5]  B. Øksendal,et al.  Optimal harvesting from a population in a stochastic crowded environment. , 1997, Mathematical biosciences.

[6]  Martin D. Smith,et al.  Economic incentives to target species and fish size: prices and fine-scale product attributes in Norwegian fisheries , 2015 .

[7]  Jim M Cushing,et al.  The effect of periodic habitat fluctuations on a nonlinear insect population model , 1997 .

[8]  Alexandru Hening,et al.  Coexistence and extinction for stochastic Kolmogorov systems , 2017, The Annals of Applied Probability.

[9]  Alexandru Hening,et al.  Random Switching in an Ecosystem with Two Prey and One Predator , 2021, SIAM J. Math. Anal..

[10]  Boris Zeide,et al.  Analysis of Growth Equations , 1993 .

[11]  Peter Chesson,et al.  Invasibility and stochastic boundedness in monotonic competition models , 1989 .

[12]  Fred Brauer,et al.  PERIODIC ENVIRONMENTS AND PERIODIC HARVESTING , 2003 .

[13]  Tien T. Phan,et al.  Harvesting of interacting stochastic populations , 2018, Journal of Mathematical Biology.

[14]  Yuri A. Kuznetsov,et al.  Multiple attractors, catastrophes and chaos in seasonally perturbed predator-prey communities , 1993 .

[15]  G. Yin,et al.  Optimal harvesting strategies for stochastic ecosystems , 2017 .

[16]  Chao Zhu,et al.  Optimal control of the risk process in a regime-switching environment , 2010, Autom..

[17]  Antoine Bourquin Persistence in randomly switched Lotka-Volterra food chains , 2021 .

[18]  An optimal harvesting policy for a logistic model in a randomly varying environment , 1981 .

[19]  P. Chesson General theory of competitive coexistence in spatially-varying environments. , 2000, Theoretical population biology.

[20]  H. Kushner Numerical Methods for Stochastic Control Problems in Continuous Time , 2000 .

[21]  Alan Hastings,et al.  Seasonality in ecology: Progress and prospects in theory , 2018, Ecological Complexity.

[22]  Alexandru Hening,et al.  Harvesting and seeding of stochastic populations: analysis and numerical approximation , 2019, Journal of mathematical biology.

[23]  Elena Braverman,et al.  Continuous versus pulse harvesting for population models in constant and variable environment , 2008, Journal of mathematical biology.

[24]  M. Fan,et al.  Optimal harvesting policy for single population with periodic coefficients. , 1998, Mathematical biosciences.

[25]  Sebastian J. Schreiber,et al.  Persistence in fluctuating environments , 2010, Journal of mathematical biology.

[26]  W. Grassman Approximation and Weak Convergence Methods for Random Processes with Applications to Stochastic Systems Theory (Harold J. Kushner) , 1986 .

[27]  Alexandru Hening,et al.  Dynamical systems under random perturbations with fast switching and slow diffusion: Hyperbolic equilibria and stable limit cycles , 2021 .

[28]  Alexandru Hening,et al.  Asymptotic harvesting of populations in random environments , 2017, Journal of Mathematical Biology.

[29]  Alexandru Hening,et al.  Stationary distributions of persistent ecological systems , 2021, Journal of mathematical biology.

[30]  Chao Zhu,et al.  On singular control problems with state constraints and regime-switching: A viscosity solution approach , 2012, Autom..

[31]  M. Bohner,et al.  Optimal harvesting policy for the Beverton--Holt model. , 2016, Mathematical biosciences and engineering : MBE.

[32]  M. J.,et al.  Two Species Competition in a Periodic Environment * , 2004 .

[33]  George Yin,et al.  Certain properties related to well posedness of switching diffusions , 2017, 1706.06670.

[34]  Thomas Lim,et al.  Optimal exploitation of a resource with stochastic population dynamics and delayed renewal , 2018, Journal of Mathematical Analysis and Applications.

[35]  George Yin,et al.  Discrete-time singularly perturbed Markov chains: aggregation, occupation measures, and switching diffusion limit , 2003, Advances in Applied Probability.

[36]  Alexandru Hening,et al.  On a Predator-Prey System with Random Switching that Never Converges to its Equilibrium , 2017, SIAM J. Math. Anal..

[37]  George Yin,et al.  Optimal harvesting strategies for stochastic competitive Lotka-Volterra ecosystems , 2015, Autom..

[38]  G. Sylvia Market Information and Fisheries Management: A Multiple-Objective Analysis , 1994 .

[39]  Alexandru Hening,et al.  The competitive exclusion principle in stochastic environments , 2018, Journal of Mathematical Biology.

[40]  Asaf Cohen,et al.  Optimal ergodic harvesting under ambiguity , 2021 .

[41]  M. Osborne Brownian Motion in the Stock Market , 1959 .

[42]  Jim M Cushing,et al.  Periodic Time-Dependent Predator-Prey Systems , 1977 .

[43]  Harvesting in a seasonal environment , 1988 .

[44]  Chao Zhu,et al.  On Optimal Harvesting Problems in Random Environments , 2010, SIAM J. Control. Optim..

[45]  Mark S Boyce,et al.  Harvesting in seasonal environments , 2005, Journal of mathematical biology.

[46]  Luis H. R. Alvarez,et al.  Optimal harvesting of stochastically fluctuating populations , 1998 .

[47]  Jianhai Bao,et al.  Permanence and Extinction of Regime-Switching Predator-Prey Models , 2015, SIAM J. Math. Anal..

[48]  Luis H. R. Alvarez,et al.  Singular stochastic control in the presence of a state-dependent yield structure , 2000 .

[49]  C. Winsor,et al.  The Gompertz Curve as a Growth Curve. , 1932, Proceedings of the National Academy of Sciences of the United States of America.

[50]  Gang George Yin,et al.  Numerical methods for controlled regime-switching diffusions and regime-switching jump diffusions , 2006, Autom..