多渔业管理目标下最优收获控制规则的综合函数形式

IF 1.9 2区农林科学 Q2 FISHERIES

Canadian Journal of Fisheries and Aquatic Sciences Pub Date : 2023-07-03 DOI:10.1139/cjfas-2022-0195

Tatsunori Yagi, T. Yamakawa

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引用次数: 0

摘要

对于世界上许多渔业来说，捕捞控制规则是支持决策的主要工具。我们之前澄清了HCR的最佳形状，以实现多个渔业管理目标（最大化平均捕获量、减少产量变化和避免种群崩溃），并通过数值估计HCR中21个生物参考点（BRP）的最佳值来确保对生物量估计误差的稳健性。然而，对于实际管理，需要一种简单但全面的功能形式来模拟最优HCR，因为使用许多BRP进行数值HCR优化是耗时的。在这里，我们引入了三个代表复合管理目标HCR绩效的目标效用函数（U1–U3）：均值-方差效用函数，其中收益率变化的绩效指标是收益率的标准差（U1）或年平均方差（U2），以及恒定相对风险规避效用函数（U3）。我们推导了两个方程来模拟最优HCR，其中三个调整参数对应于管理目标和不同程度的估计误差。这些方程将通过调整参数值显示预期捕获量和风险，帮助利益相关者讨论所需的管理策略。

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A comprehensive functional form of the optimal harvest control rule for multiple fishery management objectives

For many of the world's fisheries, harvest control rules (HCRs) are the main tools for supporting decision-making. We previously clarified the optimal shape of the HCR to achieve multiple fisheries management objectives (maximising average catch, reducing variation in yields, and avoiding stock collapse) and ensure robustness to estimation errors in biomass by numerically estimating the optimal values of the 21 biological reference points (BRPs) comprised in the HCR. However, for actual management, a simple but comprehensive functional form to emulate the optimal HCR is desirable, as numerical HCR optimisation with many BRPs is time-consuming. Here, we introduced three objective utility functions ( U1– U3) representing HCR performance for composite management objectives: mean–variance utility functions, where the performance indicator for variation in yields is the standard deviation ( U1) or the annual average variance ( U2) of yields, and the constant relative risk aversion utility function ( U3). We derived two equations to emulate the optimal HCRs with three adjusting parameters corresponding to the management objectives and different magnitudes of estimation errors. These equations will help stakeholders discuss desired management strategies by showing expected catch and risk by adjusting the parameter values.

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来源期刊

Canadian Journal of Fisheries and Aquatic Sciences 农林科学-海洋与淡水生物学

CiteScore

4.60

自引率

12.50%

发文量

148

审稿时长

6-16 weeks

期刊介绍： The Canadian Journal of Fisheries and Aquatic Sciences is the primary publishing vehicle for the multidisciplinary field of aquatic sciences. It publishes perspectives (syntheses, critiques, and re-evaluations), discussions (comments and replies), articles, and rapid communications, relating to current research on -omics, cells, organisms, populations, ecosystems, or processes that affect aquatic systems. The journal seeks to amplify, modify, question, or redirect accumulated knowledge in the field of fisheries and aquatic science.