A Progressive Hedging Approach to Solve Harvest Scheduling Problem under Climate Change

García-Gonzalo, Jordi; Pais, Cristóbal; Bachmatiuk, Joanna; Barreiro, Susana; Weintraub, Andrés

doi:10.3390/f11020224

Cited by 11 publications

(14 citation statements)

References 40 publications

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“…Indeed, the stochastic solution is robust to different climate scenario whereas, the deterministic one is infeasible to many of the tested climate scenarios. These results are in line with the ones obtained by [12,13]. The infeasibility of the deterministic solution stems mainly from the fact that the wood flow constraints are violated due to an intensive harvest in early periods.…”

Section: Discussionsupporting

confidence: 89%

“…In forestry, this method is well suited for harvest scheduling problem with wood price and demand uncertainties because we can extract samples from historical demand and price without the need to model the price like done in [10,28]. Compared to stochastic programming which require the so-called non-anticipativity constraints [13,29], SAA model is relatively smaller in terms of number of constraints (and possibly in terms of number of variables, depending on the formulation) since it does not require such constraints.…”

Section: Discussionmentioning

confidence: 99%

“…Regarding climate change data, we used the information of climate change forecast with statistical models developed in [30]. Unlike the data from [11][12][13], which originated from a process-based modeling, statistical models of forest growth under climate change are much more common (for e.g [31]). Hence, the method developed in this study can easily be extended to other forest systems.…”

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 94%

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Multistage Sample Average Approximation for Harvest Scheduling under Climate Uncertainty

Bagaram¹,

Tóth²

2020

Preprint

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Forest planners have traditionally used expected growth and yield coefficients to predict future merchantable timber volumes. However, because climate change affects forest growth, the typical forest planning methods using expected value of forest growth can lead to sub-optimal harvest decisions. We proposed in this paper to formulate the harvest planning with growth uncertainty due to climate change problem as a multistage stochastic optimization problem and use sample average approximation (SAA) as a tool for finding the best set of forest units that should be harvested in the first period even though we have a limited knowledge of what future climate will be. The objective of the harvest planning model is to maximize the expected value of the net present value (NPV) considering the uncertainty in forest growth and thus in revenues from timber harvest. The proposed model was tested on a small forest with 89 stands and the numerical results showed that the approach allows to have superior solutions in terms of net present value and robustness in face of different climate scenarios compared to the approach using the expected growth and yield. The SAA methods requires to generate samples from the distribution of the random parameter. Our results suggested that a sampling scheme that focuses on generating high number of samples in distant future stages is favorable compared to having large sample sizes for the near future stages. Finally, we demonstrated that, depending on the level of forest growth change, ignoring this uncertainty can negatively affect forest resources sustainability.

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Section: Discussionsupporting

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 94%

See 2 more Smart Citations

Multistage Sample Average Approximation for Harvest Scheduling under Climate Uncertainty

Bagaram¹,

Tóth²

2020

Preprint

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show abstract

“…The authors assessed how climate change affected the management decisions of a Eucalyptus forest in Portugal with a planning horizon of 15 years. A similar study was conducted by Álvarez-Miranda et al [12], Garcia-Gonzalo et al [13] using the same dataset. In addition to optimization methods for incorporating climate change in forest harvest scheduling, some authors invested in developing decision support systems (DSSs).…”

Section: Introductionmentioning

confidence: 58%

Multistage Sample Average Approximation for Harvest Scheduling under Climate Uncertainty

Bagaram

Tóth

2020

Forests

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Forest planners have traditionally used expected growth and yield coefficients to predict future merchantable timber volumes. However, because climate change affects forest growth, the typical forest planning methods using expected value of forest growth can lead to sub-optimal harvest decisions. In this paper, we propose to formulate the harvest planning with growth uncertainty due to climate change problem as a multistage stochastic optimization problem and use sample average approximation (SAA) as a tool for finding the best set of forest units that should be harvested in the first period even though we have a limited knowledge of what future climate will be. The objective of the harvest planning model is to maximize the expected value of the net present value (NPV) considering the uncertainty in forest growth and thus in revenues from timber harvest. The proposed model was tested on a small forest with 89 stands and the numerical results showed that the approach allows to have superior solutions in terms of net present value and robustness in face of different growth scenarios compared to the approach using the expected growth and yield. The SAA method requires to generate samples from the distribution of the random parameter. Our results suggested that a sampling scheme that focuses on generating high number of samples in distant future stages is favorable compared to having large sample sizes for the near future stages. Finally, we demonstrated that, depending on the level of forest growth change, ignoring this uncertainty can negatively affect forest resources sustainability.

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An Updated Review of Spatial Forest Planning: Approaches, Techniques, Challenges, and Future Directions

Baskent,

Borges,

Kašpar

2024

Curr. For. Rep.

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Purpose of Review The spatial forest planning concept has evolved as an essential component of the forest management planning process. The development of both exact and heuristic modeling techniques as analytical solution techniques have seen significant progress in application to spatial forest planning over the last two decades. This paper aims at providing a comprehensive review of the current state of spatial forest planning in both scope and depth, focusing on different approaches and techniques used, the challenges faced, and the potential future developments. For that purpose, we conduct a world-wide literature review and an extensive analysis of the status and trends over the past two decades in spatial forest planning. Recent Findings The literature review indicates that recent advancements have led to the development of new algorithms/formulations for addressing spatial constraints in forest planning with exact solution techniques. Nevertheless, it highlights further that heuristic techniques are still widely used, especially in large real-world problems that encompass multiple ecosystem services and constraints. Besides the provisioning services, there has been a noticeable increase in the proportion of regulating, supporting and cultural services addressed in objective functions of forest management planning models. Adjacency/green-up relationships, opening size, core area, wildlife habitat and the spatial arrangement of fuel treatments have been considered as indicators to address the provision of these services and spatial forest problem. Summary We pinpoint persistent challenges to using exact modeling techniques to address large real problems with multiple ecosystems services. We highlight further that determining the optimal combination and values of heuristic parameters and assessing the quality of heuristic solutions remains a central challenge. Finally, we highlight the potential of artificial intelligence to overcome computational obstacles to the application of both exact and heuristic techniques to spatially explicit forest management planning.

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A Progressive Hedging Approach to Solve Harvest Scheduling Problem under Climate Change

Cited by 11 publications

References 40 publications

Multistage Sample Average Approximation for Harvest Scheduling under Climate Uncertainty

Multistage Sample Average Approximation for Harvest Scheduling under Climate Uncertainty

Multistage Sample Average Approximation for Harvest Scheduling under Climate Uncertainty

An Updated Review of Spatial Forest Planning: Approaches, Techniques, Challenges, and Future Directions

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