Can Bayesian Networks be Used to Prioritize Restoration of Chinook Salmon Spawning Habitat in Data Poor Northern California Watersheds? PDF Download
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Author: Steven Michael Brumbaugh
Publisher:
ISBN:
Category :
Languages : en
Pages : 148
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Book Description
California's native salmonid populations are declining, as evident by the 2008 fishing closures on one historically abundant species, Chinook Salmon (Oncorhynchus tshawytscha). One major impact on the spring-run of Chinook Salmon within the Central Valley has been the damming of natal rivers, severely limiting available spawning habitat. Additionally, many of the streams used by spring-run Chinook Salmon lack extensive habitat data, such as substrate composition, velocity, depth, and woody debris availability, and specific factors limiting spawning habitat suitability are poorly understood. Bayesian Networks are one modeling method that could help to understand these systems and direct restoration efforts toward the most limiting factors within a watershed. These networks are capable of incorporating quantitative data (e.g., derived from empirical studies, literature review, and publicly available spatial data) and qualitative data (e.g., expert elicitation), making them a powerful tool for decision making in data-poor environments. Bayesian Networks are also easily updatable as new empirical data become available. I constructed a Bayesian Network for a Northern California stream, Deer Creek in Tehama County, to provide a useful tool for guiding restoration of spring-run Chinook Salmon spawning habitat. I developed the network using habitat variables thought to be indicators of habitat quality, including stream slope, average width, mean minimum coniferous cover from above, soil type, water year type, and potential existence of a partial barrier downstream. I used the Norsys Netica software to establish the Bayesian Network, and applied this network to each subreach (defined in this context as a riffle-pool stream segment) to determine the suitability of each subreach for Chinook Salmon spawning. Probability of redd (spawning nest site) presence over 50% was used to indicate good habitat suitability for spawning. Redd data was split into two independent sets. I used redd data from one 6 km reach to fit the model (i.e., develop conditional probabilities by back calculating from known outcomes), and used redd data from a second 6 km reach for prediction and comparison with the empirical data for purposes of model validation. I used two types of model validation. I conducted a sensitivity analysis on the network, to determine the influence of each independent variable and determine whether it had an unexpected or disproportionate effect on the outcome. I also conducted an ANOVA comparing redd densities from subreaches predicted to be good spawning habitat against those predicted to be poor spawning habitat by the network, to assess if there was a statistically significant difference between the two. Of the four scenarios I modeled with the network, three exhibited significantly higher redd densities in subreaches designated as good spawning habitat according to probability of redd occurrence (National Hydrography Dataset streamline under dry conditions, traced streamline under dry conditions, and traced streamline under non-dry conditions). The National Hydrography Dataset (NHD) streamline under non-dry conditions overestimated likelihood of redd presence. This was likely due to an exaggerated effect of mean minimum coniferous cover from above within the NHD model. My results, particularly using the traced streamline network, indicate that Bayesian Networks can be used to predict habitat use and prioritize spawning habitat restoration for Chinook Salmon in a data-poor northern California watershed.
Author: Steven Michael Brumbaugh
Publisher:
ISBN:
Category :
Languages : en
Pages : 148
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Book Description
California's native salmonid populations are declining, as evident by the 2008 fishing closures on one historically abundant species, Chinook Salmon (Oncorhynchus tshawytscha). One major impact on the spring-run of Chinook Salmon within the Central Valley has been the damming of natal rivers, severely limiting available spawning habitat. Additionally, many of the streams used by spring-run Chinook Salmon lack extensive habitat data, such as substrate composition, velocity, depth, and woody debris availability, and specific factors limiting spawning habitat suitability are poorly understood. Bayesian Networks are one modeling method that could help to understand these systems and direct restoration efforts toward the most limiting factors within a watershed. These networks are capable of incorporating quantitative data (e.g., derived from empirical studies, literature review, and publicly available spatial data) and qualitative data (e.g., expert elicitation), making them a powerful tool for decision making in data-poor environments. Bayesian Networks are also easily updatable as new empirical data become available. I constructed a Bayesian Network for a Northern California stream, Deer Creek in Tehama County, to provide a useful tool for guiding restoration of spring-run Chinook Salmon spawning habitat. I developed the network using habitat variables thought to be indicators of habitat quality, including stream slope, average width, mean minimum coniferous cover from above, soil type, water year type, and potential existence of a partial barrier downstream. I used the Norsys Netica software to establish the Bayesian Network, and applied this network to each subreach (defined in this context as a riffle-pool stream segment) to determine the suitability of each subreach for Chinook Salmon spawning. Probability of redd (spawning nest site) presence over 50% was used to indicate good habitat suitability for spawning. Redd data was split into two independent sets. I used redd data from one 6 km reach to fit the model (i.e., develop conditional probabilities by back calculating from known outcomes), and used redd data from a second 6 km reach for prediction and comparison with the empirical data for purposes of model validation. I used two types of model validation. I conducted a sensitivity analysis on the network, to determine the influence of each independent variable and determine whether it had an unexpected or disproportionate effect on the outcome. I also conducted an ANOVA comparing redd densities from subreaches predicted to be good spawning habitat against those predicted to be poor spawning habitat by the network, to assess if there was a statistically significant difference between the two. Of the four scenarios I modeled with the network, three exhibited significantly higher redd densities in subreaches designated as good spawning habitat according to probability of redd occurrence (National Hydrography Dataset streamline under dry conditions, traced streamline under dry conditions, and traced streamline under non-dry conditions). The National Hydrography Dataset (NHD) streamline under non-dry conditions overestimated likelihood of redd presence. This was likely due to an exaggerated effect of mean minimum coniferous cover from above within the NHD model. My results, particularly using the traced streamline network, indicate that Bayesian Networks can be used to predict habitat use and prioritize spawning habitat restoration for Chinook Salmon in a data-poor northern California watershed.
Author: Justin P. Bissell
Publisher:
ISBN:
Category : Chinook salmon
Languages : en
Pages : 209
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Restoration of anadromous salmonid habitat is of primary importance to the economic, historical, and cultural geography of the Pacific Northwest. Derivation and use of geospatial habitat models as guides to pinpoint key areas where limited restoration funding can be cost-effectively employed is of great importance. To this purpose, 1 meter resolution lidar-derived Digital Elevation Model data was acquired for the Indian Creek and neighboring watersheds in Mendocino County, California, and used together with field-acquired geomorphic stream data to geospatially model stream widths, depths, and streambank morphology. These geospatial covariates were field-verified in selected locations and then used in conjunction with field surveyed habitat presence data and substrate data to model potential anadromous salmonid species spawning habitat. Probability surfaces, each comprising the areal extent of the Indian Creek stream system and representing the probability for spawning habitat occurrence, were developed for each of the species of interest. The mean area under the curve (AUC) for 100 model replications for Chinook, Coho, and Steelhead were 0.954, 0.951, and 0.958, with standard deviations of 0.036, 0.034, and 0.036, respectively. In contrast to other models that solely use linear lengths of stream, the models developed in this work incorporate modeled stream bankfull widths and modeled stream corridor morphology, thus allowing additional interpretation and prediction involving the amount of species' use of specific streams and watersheds. Models were field-verified by California Department of Fish and Wildlife fisheries biologist staff and Pacific Watershed Associates engineering geologists and field scientist staff as being representative of actual field conditions, thus assuring the value of modeling results and methodology in future projects and research.
Author:
Publisher:
ISBN:
Category : Chinook salmon
Languages : en
Pages : 60
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Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 186
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The Pacific Northwest National Laboratory conducted this study for the Bonneville Power Administration (BPA) with funding provided through the Northwest Power and Conservation Council(a) and the BPA Fish and Wildlife Program. The study was conducted in the Hanford Reach of the Columbia River. The goal of study was to determine the physical habitat factors necessary to define the redd capacity of fall Chinook salmon that spawn in large mainstem rivers like the Hanford Reach and Snake River. The study was originally commissioned in FY 1994 and then recommissioned in FY 2000 through the Fish and Wildlife Program rolling review of the Columbia River Basin projects. The work described in this report covers the period from 1994 through 2004; however, the majority of the information comes from the last four years of the study (2000 through 2004). Results from the work conducted from 1994 to 2000 were covered in an earlier report. More than any other stock of Pacific salmon, fall Chinook salmon (Oncorhynchus tshawytscha) have suffered severe impacts from the hydroelectric development in the Columbia River Basin. Fall Chinook salmon rely heavily on mainstem habitats for all phases of their life cycle, and mainstem hydroelectric dams have inundated or blocked areas that were historically used for spawning and rearing. The natural flow pattern that existed in the historic period has been altered by the dams, which in turn have affected the physical and biological template upon which fall Chinook salmon depend upon for successful reproduction. Operation of the dams to produce power to meet short-term needs in electricity (termed power peaking) produces unnatural fluctuations in flow over a 24-hour cycle. These flow fluctuations alter the physical habitat and disrupt the cues that salmon use to select spawning sites, as well as strand fish in near-shore habitat that becomes dewatered. The quality of spawning gravels has been affected by dam construction, flood protection, and agricultural and industrial development. In some cases, the riverbed is armored such that it is more difficult for spawners to move, while in other cases the intrusion of fine sediment into spawning gravels has reduced water flow to sensitive eggs and young fry. Recovery of fall Chinook salmon populations may involve habitat restoration through such actions as dam removal and reservoir drawdown. In addition, habitat protection will be accomplished through set-asides of existing high-quality habitat. A key component to evaluating these actions is quantifying the salmon spawning habitat potential of a given river reach so that realistic recovery goals for salmon abundance can be developed. Quantifying salmon spawning habitat potential requires an understanding of the spawning behavior of Chinook salmon, as well as an understanding of the physical habitat where these fish spawn. Increasingly, fish biologists are recognizing that assessing the physical habitat of riverine systems where salmon spawn goes beyond measuring microhabitat like water depth, velocity, and substrate size. Geomorphic features of the river measured over a range of spatial scales set up the physical template upon which the microhabitat develops, and successful assessments of spawning habitat potential incorporate these geomorphic features. We had three primary objectives for this study. The first objective was to determine the relationship between physical habitats at different spatial scales and fall Chinook salmon spawning locations. The second objective was to estimate the fall Chinook salmon redd capacity for the Reach. The third objective was to suggest a protocol for determining preferable spawning reaches of fall Chinook salmon. To ensure that we collected physical data within habitat that was representative of the full range of potential spawning habitat, the study area was stratified based on geomorphic features of the river using a two-dimensional river channel index that classified the river cross section into one of four shapes based on channel symmetry, depth, and width. We found that this river channel classification system was a good predictor at the scale of a river reach ((almost equal to)1 km) of where fall Chinook salmon would spawn. Using this two-dimensional river channel index, we selected study areas that were representative of the geomorphic classes. A total of nine study sites distributed throughout the middle 27 km of the Reach (study area) were investigated. Four of the study sites were located between river kilometer 575 and 580 in a section of the river where fall Chinook salmon have not spawned since aerial surveys were initiated in the 1940s; four sites were located in the spawning reach (river kilometer [rkm] 590 to 603); and one site was located upstream of the spawning reach (rkm 605).
Author: G. Mathias Kondolf
Publisher:
ISBN:
Category : Nature
Languages : en
Pages : 164
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Author: Terry J. Mills
Publisher:
ISBN:
Category : Chinook salmon
Languages : en
Pages : 64
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Author: Robert F. Raleigh
Publisher:
ISBN:
Category : Chinook salmon
Languages : en
Pages : 80
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![Biological Opinion [that Address the Potential Effects on Sacramento River Winter-run Chinook Salmon from the Bureau of Reclamation's Proposed Los Vaqueros Project] PDF](https://books.google.com/books/content/images/frontcover/ZBo-3fXqx-YC?fife=w80-h100)
Author:
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ISBN:
Category : Chinook salmon
Languages : en
Pages : 36
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Author: Michael Bishopp
Publisher:
ISBN:
Category : Chinook salmon
Languages : en
Pages : 197
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Author: Eric John Andersen
Publisher:
ISBN:
Category : Culverts
Languages : en
Pages : 200
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Re-establishing connectivity is a primary restoration activity for enhancing the recovery of migratory fishes, but actions are often limited by lack of funds and understanding of the benefits of individual projects. The objective of this study was to develop a Bayesian Network (BN) to assess priorities for restoration of aquatic connectivity as accomplished by replacement of culverts at road stream crossings that may act as passage barriers to winter run Steelhead (Oncorhynchus mykiss) in the North and South Santiam Rivers (state of Oregon). The model predicted the probability of biological benefit obtained by removal or replacement of a culvert. The degree of passage impairment, habitat suitability and probability of habitat use influenced the predicted biological benefit. This model structure was populated with conditional probability table values derived from expert opinion and a Bayesian learning algorithm to produce outcomes based on different model inputs. Both models were then used to assess 141 data scenarios land and fishery managers would likely encounter. Results of the BN indicate that culverts that 1) are barriers to adult and juvenile steelhead, 2) are located in Oregon Department of Environmental Quality (DEQ) designated cold core water habitat, 3) have a high capacity for rearing juvenile fish, and 4) have a high probability of habitat use will provide the highest overall benefit. As anticipated, culverts that are not barriers to upstream migrating fish provided the lowest benefit, regardless of habitat suitability or habitat use. In addition to specific results for the Santiam basin, comparison between the two models and across information scenarios illustrated the sensitivity of such models to various conditions likely to be encountered by decision makers; in general, the two models agreed when all input nodes were engaged by having a state value entered, yet disagreed as fewer input nodes were engaged. The passage impairment of a culvert and the probability of habitat use exerted a strong influence on model output. Finally, this model may serve as a template for providing a coarse evaluation of culverts in other basins or may be a foundation upon which additional nodes may be added.
