Individual-based model of sympatric populations of brown and rainbow trout for instream flow assessment: model description and calibration
Authored by Steven F Railsback, HI Jager, Winkle W Van, BD Holcomb, TK Studley, JE Baldrige
Date Published: 1998
DOI: 10.1016/s0304-3800(98)00065-9
Sponsors:
United States Department of Energy (DOE)
Electric Power Research Institute (EPRI)
Pacific Gas & Electric (PG&E)
Southern California Edison (SCE)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
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Mathematical description
Model Code URLs:
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Abstract
This paper describes an individual-based model of sympatric populations
of brown and rainbow trout in a stream habitat. The model provides a
tool for projecting flow and temperature effects on trout populations by
linking the hydraulic component of the instream how incremental
methodology/physical habitat simulation system (IFIM/PHABSIM) to an
individual-based population model. PHABSIM simulates the spatial
distribution of depth and velocity at different flows, and indirectly, the availability of spawning habitat, cover and feeding station. The
individual-based model simulates reproduction, growth and mortality of
individual trout as a function of flow and temperature. Population
dynamics arise from the survival and reproduction of individual trout.
The spatially explicit nature of the model permits evaluation of
behavioral responses used by fish to changes in physical habitat. The
model has been calibrated to a stream segment in the North Fork Middle
Fork Tule River, California. Selected parameters were adjusted to
calibrate the model for length and abundance (including production of a
new year class) at the end of 1-year simulations for each of 9 years.
Predicted and observed lengths were in good agreement, although neither
varied appreciably among years. Predicted and observed abundances were
not in as good agreement, and differed considerably for some years.
These differences reflect a combination of uncertainties in the field
data and uncertainties in the model structure and parameter values.
Fifty-year simulations indicated that model projections of length and
abundance were stationary, although abundance values fluctuated
considerably. Seven advantages for using simulation models of this type
are emphasized. How to most effectively interpret results from such
simulation models as part of instream flow environmental assessments
remains a challenge. Variability and uncertainty in both field data and
replicate model simulations are realities that have implications for
scientists, resource managers, and regulators in projecting growth and
abundance responses of fish populations to alternative flow or
temperature regimes. (C) 1998 Elsevier Science B.V. All rights reserved.
Tags
Habitat use
Foraging behavior
Patchy environment
Salvelinus-fontinalis
Sockeye-salmon
Smallmouth bass
Microhabitat use
Error analysis
Incremental methodology
Salmo-trutta l