Aaron B. Hoskins scite author profile

There is significant value in the data collected by satellites during and after a natural disaster. The current operating paradigm in practice is for satellites to passively collect data when they happen to fly over a disaster location. Conversely, this article considers the alternative approach of actively maneuvering satellites to fly directly overhead of the disaster site on a routine basis. Toward this end, we seek to compute a satellite constellation design that minimizes the expected maneuver costs for monitoring an unknown forest fire. In this article, we present a 2‐stage stochastic programing model for this problem as well as a accelerated L‐shaped decomposition approach. A comparison between our approach and the current operating paradigm indicates that our solution provides longer duration data collections and a greater number of data collections. Analysis also shows that our proposed solution is robust over a wide array of scenarios.

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Spacecraft Formation Optimization with a Multi-Impulse Design

Hoskins

Atkins

2005

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An attacker‐defender model for analyzing the vulnerability of initial attack in wildfire suppression

Rashidi

Medal

Hoskins

2018

Naval Research Logistics

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Wildfire managers use initial attack (IA) to control wildfires before they grow large and become difficult to suppress. Although the majority of wildfire incidents are contained by IA, the small percentage of fires that escape IA causes most of the damage. Therefore, planning a successful IA is very important. In this article, we study the vulnerability of IA in wildfire suppression using an attacker-defender Stackelberg model. The attacker's objective is to coordinate the simultaneous ignition of fires at various points in a landscape to maximize the number of fires that cannot be contained by IA. The defender's objective is to optimally dispatch suppression resources from multiple fire stations located across the landscape to minimize the number of wildfires not contained by IA. We use a decomposition algorithm to solve the model and apply the model on a test case landscape. We also investigate the impact of delay in the response, the fire growth rate, the amount of suppression resources, and the locations of fire stations on the success of IA.KEYWORDS attacker-defender model, critical infrastructure, initial attack, Stackelberg game, vulnerability assessment, wildfire management 1 120

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Mitigating a pyro-terror attack using fuel treatment

2018

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Aaron B. Hoskins

Satellite constellation design for forest fire monitoring via a stochastic programing approach

Spacecraft Formation Optimization with a Multi-Impulse Design

An attacker‐defender model for analyzing the vulnerability of initial attack in wildfire suppression

Mitigating a pyro-terror attack using fuel treatment

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