top of page

Introductory fish population dynamics and stock assessment

Course name: Introductory fish population dynamics and stock assessment

Semester: 105-1

Department:

Instructor: Yi-Jay Chang

Course No.: FISH 808

Credit: 3

Year/Half year: Half year

Required/Selected: Selected

Class time: TBD

Notes: This course is lectured in English

Website: TBD

 

Description

This course is a complete review of basic population dynamics and stock assessment, methods to be applied at different level of data, and a review of relevant computer programs. Course covers introduction, data used in stock assessment (catch, abundance, and life history), population dynamics models, determination of stock status, biological reference points, and future forecast.

 

Assessment models of per-recruit model, biomass dynamics model, lagged recruitment, survival and growth model, and age-structured production model will be included. Student will be familiar with terms in fish population dynamics (e.g.., fishing mortality, catchability, selectivity, steepness, etc.) and proficient in parameter estimation (e.g., growth, mortality, unfished biomass, MSY), as well as the uncertainty, of an exploited fish population, and evaluation of harvest restrictions for fisheries management problems. The course draws examples from real fisheries in the world and provides student broad experiences of various fishery data and fish biology. The course is primarily for students of fisheries and marine ecology, but should also appeal to those interested in conservation ecology and ecological modelling.

 

Objective

The main objective of the course was to become proficient with background and tools to conduct basic stock assessments for fisheries. Student will develop professional skills of data analysis, quantitative fish population modelling, and theory and implication of fish harvest management. Student will carry out fisheries data analysis, modelling, and interpretation on a regular basis throughout the course. The course expects student will develop their own model and application. Course will provide basic programming training by following the examples using Excel and R.

 

Prerequisites

Recommend having basic knowledge of Statistics (e.g., LS3022-Biostatistics) or the equivalent is recommended. 

 

Grade

Participation/attendance (10%)

Homework (70%): Total five homeworks.

Final exam (20%): This will be 50-minute closed-book exams on DATE [TBD] that test knowledge of materials from the previous lectures, readings and homework exercise.

 

Textbook

 Haddon, M. 2001. Modelling and Quantitative Methods in Fisheries. Chapman and Hall, London, 406 pp.

 

Hilborn, R., Walters, C.J., 1992. Quantitative Fisheries Stock Assessment: Choice, Dynamics and Uncertainty. Chapman and Hall, New York, 570 pp.

 

Office hours

TBD

 

Course outline

Lecture 1

Introduction and overview: what is stock assessment?

 

Lecture 2

Fish and “fished” population dynamics

              Lab: demo

 

Lecture 3

Stock assessment-Key principle and components

 

Lecture 4

Data collection (sampling) and stock assessment

               Lab: logbook and observer data analysis

 

Lecture 5

Modelling Growth -1

               Lecture

               Lab: modeling the growth curves, model selection, age-length key

               Fitting model to data

 

Lecture 6

Modelling Growth -2

               Length frequency method

               Lab: maximum likelihood of length frequency method

 

Lecture 7

Modelling Growth -3

               Modeling growth of crustacean, growth transition matrix, stepwise growth curve

               Lab: estimation growth of crustacean

 

Lecture 8

Fisheries term: catchability, mortality, selectivity

               Lab: estimation of mortality              

 

Lecture 9

Reproduction, stock-recruitment, steepness

               Lab: Fitting stock-recruitment curves

 

Lecture 10

Abundance indices, catch-per-unit-effort, and CPUE standardization

 

Lecture 11

Abundance indices, catch-per-unit-effort, and CPUE standardization

              Lab: CPUE standardization, Generalized Linear Models

 

Lecture 12

Per recruit analysis, biological reference points

               Lab: Equilibrium yield per recruit model

              

Lecture 13

Biomass dynamics models

 

Lecture 14

Biomass dynamics models

               Lab: fitting biomass dynamics models

 

Lecture 15

Include S-R relationship into stock assessment model

               Lab: Lagged recruitment, survival and growth models

 

Lecture 16

Age-Structured Production Models

               Lab: Age-Structured Production Models

 

Lecture 17

Age-Structured Production Models-II

bottom of page