The overutilization of fish stocks, the overcapitalization of fisheries, the removal of associated benefits to society and growing concern over the conservation of marine biodiversity have resulted in a line of fisheries research that is multidisciplinary, dynamic and precautionary in approach. All the biological, ecological and economic factors need to be analysed if the forces regulating the dynamics of a fishery are to be appraised. This publication looks at the assumptions underlying the optimal allocation of renewable natural resources; lists the bioeconomic points of reference resulting from analysis of fisheries is supposed conditions of equilibrium; analysis bioeconomic models according to ecological interdependence factors (such as competition and predation) and technological factors (such as competition between fleets with different fishing capacity); offers a time-series analysis of fisheries and estimates the level of optimal effort; proposes mathematical models applied to bioeconomic analysis to support fisheries management plans; refutes the assumption of uniform resource distribution, incorporating a spatial dimension in fisheries dynamics analysis; and expounds basic elements of decision-making theory and criteria that reflect different attitudes to risk aversion in fisheries management. Contents: Chapter 1: Inherent Characteristics of Fish Stocks, (1) Optimal Allocation of Renewable Resources: Basic Assumptions, (2) The Failure in the Optimal Allocation of Fishery Resources, (3) Fisheries Management Plans, (4) A Closing Comment, Chapter 2: Bioeconomic Models, (1) The Gordon-Schaefer Model, (2) Fleet Dynamics: A Distributed-Delay Smith s Model, (3) Yield-Mortality Models: A Bioeconomic Approach, (4) Age-Structured Bioeconomic Models, (5) Intertemporal Fisheries Analysis, Chaper 3: Ecological and Technological Interdependencies, (1) Technological Interdependencies: Heterogenous Fishing Effort, (2) Technologically Interdependent Fisheries: Two Fleets, (3) Technological Interdependencies: Sequential Fisheries, (4) Bioeconomics of Ecologically Interdependent Stocks, (5) Techno-Ecological Interdependencies, (6) Multispecies Fisheries and Experimental Management, Chapter 4: The System Science Approach in Fisheries Bioeconomics, (1) The System Simulation Approach, (2) A Numerical Example, Chapter 5: Management, (1) State Intervention Criteria, (2) Management Strategies, (3) Multiple Criteria Optimization Approach for Fisheries Management, Chapter 6: Spatial Bioeconomic Models, (1) Spatial Allocation of Fishing Intensite, (2) Short-Run Spatial Dynamics: ALLOC Model, (3) Short and Long-Run Geographic Bioeconomic Dynamics: CHART Model, (4) A Spatial Bioeconomic Model for Sedentary Fisheries: The Yellow Clam Mesodesma mactroides of Uruguay, a Study Case, Chapter 7: Risk and Uncertainty: A Precautionary Approach, (1) Precautionary Approach to Fisheries Management, (2) Sources of Uncertainty in Fisheries, (3) Management Decisions without Mathematical Probabilities, (4) Management Decisions with Mathematical Probabilities, (5) Estimation of Uncertainty in Model Parameters.