This book describes how stability theory of differential equations is used in the modeling of microbial competition, predator-prey systems, humoral immune response, and dose and cell-cycle effects in radiotherapy, among other areas that involve population biology, and mathematical ecology.
This book describes how stability theory of differential equations is used in the modeling of microbial competition, predator-prey systems, humoral immune response, and dose and cell-cycle effects in radiotherapy, among other areas that involve population biology, and mathematical ecology.
1. Persistence in Lotka-Volterra Models of Food Chains and Competition 2. Mathematical Models of Humoral Immune Response 3. Mathematical Models of Dose and Cell Cycle Effects in Multifraction Radiotherapy 4. Theoretical and Experimental Investigations of Microbial Competition in Continuous Culture 5. A Liapunov Functional for a Class of Reaction-Diffusion Systems 6. Stochastic Prey-Predator Relationships 7. Coexistence in Predator-Prey Systems 8. Stability of Some Multispecies Population Models 9. Population Dynamics in Patchy Environments 10. Limit Cycles in a Model of B-Cell Stimulation 11. Optimal Age-Specific Harvesting Policy for a Continuous Time-Population Model 12. Models Involving Differential and Integral Equations Appropriate for Describing a Temperature Dependent Predator-Prey Mite Ecosystem on Apples
1. Persistence in Lotka-Volterra Models of Food Chains and Competition 2. Mathematical Models of Humoral Immune Response 3. Mathematical Models of Dose and Cell Cycle Effects in Multifraction Radiotherapy 4. Theoretical and Experimental Investigations of Microbial Competition in Continuous Culture 5. A Liapunov Functional for a Class of Reaction-Diffusion Systems 6. Stochastic Prey-Predator Relationships 7. Coexistence in Predator-Prey Systems 8. Stability of Some Multispecies Population Models 9. Population Dynamics in Patchy Environments 10. Limit Cycles in a Model of B-Cell Stimulation 11. Optimal Age-Specific Harvesting Policy for a Continuous Time-Population Model 12. Models Involving Differential and Integral Equations Appropriate for Describing a Temperature Dependent Predator-Prey Mite Ecosystem on Apples
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