模拟捕鱼在鱼类丰度监测中的可捕性和有效性

Q3 Agricultural and Biological Sciences San Francisco Estuary and Watershed Science Pub Date : 2020-02-14 DOI:10.20944/preprints202002.0177.v1
V. Tobias
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引用次数: 1

摘要

在渔业监测中,渔获量被认为是捕捞强度、可捕性和可获得性的产物,其中可获得性被定义为现有鱼类的数量或生物量,可捕性是指渔获量率和真实种群之间的关系。生态监测项目使用单位努力渔获量(CPUE)来标准化渔获量并监测鱼类种群的变化;然而,CPUE与人群中易受采样中使用的齿轮类型影响的部分成比例,这不一定是整个人群。项目通常通过假设可捕性是恒定的来处理这个问题,但如果可捕性不是恒定的,则不可能单独使用监测数据来分离可捕性和人口规模的影响。本研究使用基于个体的模拟来分离环境条件变化对环境监测数据可捕性和可用性的影响。该模拟将采样条件模块与单个鱼类行为模块相结合,以估计从样本中逃逸的可用鱼类的比例。该方法应用于旧金山河口监测良好的鱼类三角洲气味(Hypomesus transpacificus)的案例研究,在那里,假设不断变化的水透明度可能会影响长期监测研究的可捕性。这项研究的结果表明,考虑到三角洲气味游泳能力的限制,三角洲气味丰度的明显下降不太可能是由于水透明度的变化对可捕性的影响。
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Simulated Fishing to Untangle Catchability and Availability in Fish Abundance Monitoring
In fisheries monitoring, catch is assumed to be a product of fishing intensity, catchability, and availability, where availability is defined as the number or biomass of fish present and catchability refers to the relationship between catch rate and the true population. Ecological monitoring programs use catch per unit of effort (CPUE) to standardize catch and monitor changes in fish populations; however, CPUE is proportional to the portion of the population that is vulnerable to the type of gear that is used in sampling, which is not necessarily the entire population. Programs often deal with this problem by assuming that catchability is constant, but if catchability is not constant, it is not possible to separate the effects of catchability and population size using monitoring data alone. This study uses individual-based simulation to separate the effects of changing environmental conditions on catchability and availability in environmental monitoring data. The simulation combines a module for sampling conditions with a module for individual fish behavior to estimate the proportion of available fish that would escape from the sample. The method is applied to the case study of the well-monitored fish species Delta Smelt (Hypomesus transpacificus) in the San Francisco Estuary, where it has been hypothesized that changing water clarity may affect catchability for long-term monitoring studies. Results of this study indicate that given constraints on Delta Smelt swimming ability, it is unlikely that the apparent declines in Delta Smelt abundance are due to an effect of changing water clarity on catchability.
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来源期刊
San Francisco Estuary and Watershed Science
San Francisco Estuary and Watershed Science Environmental Science-Water Science and Technology
CiteScore
2.90
自引率
0.00%
发文量
24
审稿时长
24 weeks
期刊最新文献
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