Caraco, Thomas - Department of Biological Sciences, State University of New York at Albany

• Bio 320 Ecology Fall 2010 Problem Set 3 1. In discrete time, a population with density-dependent dynamics grows according to
• Temporal Environmental Variation: Among-Generation Variance in Growth Rate
• Interested in animal behavior? Need an advanced lab to
• Virulence evolution and the timing of disease life-history events
• vol. 165, no. 6 the american naturalist june 2005 Emergence of a Convex Trade-Off between
• BIO 432 PRACTICE PROBLEMS A forager searches simultaneously for two prey types; items are encountered sequentially. The
• Geometric Mean Growth Discrete time: t, (t + 1), (t+2), ...
• JOURNAL OF ANTHROPOLOGICAL ARCHAEOLOGY 7, 329-312 (1988) An Optimal Foraging-Based Model of Hunter-Gatherer
• BIO 432: Topics for Test 2, 2011 Dispersion Economies
• UNI 101z November 9, 2004 Population Dynamics and Chaos: A Descriptive Introduction
• Interspecific Interactions 2 Species, Insight Understand Larger Communities
• BIO 432: References for Second Paper, 2010 Mate Choice and Sexual Selection
• Ideal Free Distribution (IFD) Pattern in Consumers across Resource Patches
• Foraging Behavior Thomas Caraco
• Preemptive spatial competition under a reproductionmortality constraint Andrew Allstadt a
• Evolutionary Ecology, 1988, 2, 232-252 Individual variation in the ability of Columbian
• ECOLOGY ABIO 320 FALL 2010 DR. CARACO BI 253A
• Group size, energy budgets, and population dynamic complexity
• BIO 320 Project on Population Dynamics 1. Due Wednesday, 8 December 2010, the last class meeting.
• International Association for Ecology A Linear Programming Model of Herbivore Foraging: Imprecise, Yet Successful?
• Second Problem Set 1. Consider another discrete, symmetric 2-player game. At each interaction a player
• COOPERATION: Non-relatives Mutualism, Conditional Cooperation, Reciprocal Altruism
• Should we expect population thresholds for wildlife disease?
• www.newphytologist.org 279 Blackwell Publishing Ltd
• Technology in Society 23(2):131-146 (2001) Death and the Human Environment
• Theoretical Population Biology 62, 111119 (2002) doi:10.1006/tpbi.2002.1585
• Received 5 November 2002 Accepted 3 December 2002
• vol. 172, no. 3 the american naturalist september 2008 Transmission-Recovery Trade-Offs to Study Parasite Evolution
• Virulence evolution in a virus obeys a trade-off Sharon L. Messenger1
• Ecologicalimmunology: costlyparasitedefencesandtrade-offs
• The American Society of Naturalists Herbivore Optimal Foraging: A Comparative Test of Three Models
• Economics of Sociality Recall 2-Player Game
• Publications: Thomas Caraco 1. Caraco, T. & L.L. Wolf. 1975. Ecological determinants of group sizes
• Logistic growth: Discrete-time dynamics Self-regulation Intra-specific competition
• Exploiter-Victim PredatorPrey
• References: Individual Foraging & Functional Efficiency I. Some papers on diet selection and related problems
• Fisher Waves and Front Roughening in a Two-Species Invasion Model with Preemptive Competition
• Optimization Theory in Evolution Author(s): J. Maynard Smith
• BIO 432: First Paper 1. Basic Evolutionary Biology, "Phenotypic Gambit"
• Aggregation Economy Replace general fitness function wi(Group size)
• Theoretical Population Biology 70 (2006) 464478 Invasive advance of an advantageous mutation: Nucleation theory
• A forager searches for two prey types simultaneously; items are encountered sequentially. While searching, the
• Identical Individuals? Population Structure: How Individuals Differ
• Journal of Theoretical Biology 250 (2008) 569579 Free-living pathogens: Life-history constraints and strain competition
• Bio 320 Ecology Fall 2010 Problem Set 2 1. A population of 600 individuals experiences spatial heterogeneity in its discrete-time
• Bio 320 Ecology Fall 2010 Problem Set 5 1. Consider a metapopulation with the "internal colonization" dynamics of deme
• Bio 320 Ecology Fall 2010 Problem Set 6 1. V(t) and E(t) are, respectively, prey density and predator density at time t. The
• Biotic regulation: Density-dependence Within-species: self-regulation
• Logistic Growth: Quadratic, No Time Delay, K Constant b = [K -N(0)]/N(0)
• Logistic Growth, Continuous Time Instantaneous Feedback via Self-regulation
• Survivorship Curves (Ricklefs & Miller, 1999) Type I: 3 phases, most mortality post-breeding
• Age Structured Population Growth Dynamics of Numbers in Each Age Class
• For Monday, 4 Oct 10 A population with non-overlapping generations (e.g., an annual plant) exhibits geometric
• Interspecific Competition Two Species Use Common Resource(s)
• Problems: preparation for Test 2 12 November 2010 1. Discriminate direct and indirect interactions between species. Explain
• Arrays: Arrangements of Elements 1. Matrices: Multiple Rows and Columns
• Ecological Succession Community (Ecosystem) Development
• Diversity of Ecological Communities Species Number, Richness, Diversity
• Review of Test 2, Fall 2010 1. Sp i invades Sp j at Nj = Kj. Conclude?
• My Population-Dynamics Project 1. My Question
• BIO 320 Project on Population Dynamics 1. Due Friday, 8 December 2008, the last class meeting.
• The Biosphere: Anthropogenic Impact Biosphere: World's Ecosystems
• References: Social Foraging & Functional Efficiency I. Some papers on the Ideal Free Distribution and related issues
• THE ECONOMIC ANIMAL Suppose Evolution by Natural Selection
• Risk-Sensitive Foraging Individual Search / Consumption of Food Items/Clumps
• Invited Review Linear Programming: A Mathematical Tool for Analyzing and
• International Association for Ecology Circularity in Linear Programming Models of Optimal Diet
• The American Society of Naturalists An Analysis of Diet Selection by Large Generalist Herbivores
• Population Growth Advance and Decline
• John P. Holdren Assistant to the President for Science and Technology
• Ecological invasion: spatial clustering and the critical radius
• Mark-Recapture Problem t1 Capture, mark & release 30 P. maniculatus
• Economics of the Family Equilibrium Group Size and Genetic Relatedness
• Theoretical Population Biology 69 (2006) 367384 Spatially structured superinfection and the evolution of disease virulence
• Journal of Theoretical Biology 233 (2005) 137150 Spatial dynamics of invasion: the geometry of introduced species
• Empirical Support for Optimal Virulence in a Castrating Parasite
• Harvesting can increase severity of wildlife disease epidemics
• Resource Specialist, Resource Generalist Specialize: Choose Narrow Set of Resources
• Bio 320 Ecology Fall 2010 Problem Set 1 1. At time t1 you capture, mark and release 60 individuals. At time t2 you capture 144
• TRENDS in Microbiology Vol.9 No.9 September 2001 http://tim.trends.com 0966-842X/01/$ see front matter 2001 Elsevier Science Ltd. All rights reserved. PII: S0966-842X(01)02130-8
• Modeling Population Dynamics: a Graphical Approach
• New Problem : Patch Exploitation Individual Foraging: Functional Significance
• BEHAVIOR ECOLOGY Consumer Choice Resource Diversity
• vol. 172, no. 2 the american naturalist august 2008 Decreased Overall Virulence in Coinfected Hosts
• Agonistic Behavior: Descriptive, Aggression Aggressive Resource Defense: Functional Significance
• Host Parasite Microparasites: Virus, Bacteria, Fungus, Protozoa
• Currency of Fitness in Foraging Theories Hypothesis Links Behavior to Fitness
• Challenging the trade-off model for the evolution of virulence: is virulence
• PRODUCER -SCROUNGER GAME n-Person Game
• Quantification of the effect of vaccination on transmission of avian influenza (H7N7) in chickens
• Logistic (Self-Regulated) Growth (Ricklefs & Miller 1999) Begon, Harper, Townsend, 2000
• Zonation: Position on Gradient Barnacles: Dessication
• Population Dynamics Prey V(t), Predator P(t) Equilibrium Nodes: (0, 0) and (V* = D/, P* = r/)
• Interspecific Competition Two Species Use Common Resource(s)
• Self-Regulated Population Growth Continuous time t Overlapping Generations
• Interspecific Competition & Stable Coexistence 1. Competition Resource-Limited Growth
• Logistic growth: Discrete-time dynamics Self-regulation Intra-specific competition
• Modeling Population Dynamics: a Graphical Approach
• RESOURCE COMPETITION: Ecological Result 1. Competitive Exclusion
• BIO 564 Spring 2012 Take-Home Problems 1 Show any work required to solve the problems.
• Density-Dependent Population Growth: Discrete Time Non-Overlapping Generations
• Interspecific Interactions Abstraction: 2 Species
• Host Parasite Microparasites: Virus, Bacteria, Fungus, Protozoa
• BIO 564 Spring 2012 Take-Home Problems 2 Show any work required to solve the problems.
• BIO 320: Questions from Tests and Problem Sets BIO 564 Students: Consider this document a preview/sample of the ma-
• UNI 101z November 9, 2004 Population Dynamics and Chaos: A Descriptive Introduction
• BIO 564/Principles of Ecology/Spring 2012/Test Questions Inspired by, but not copied from, past and present QEI questions in Ecology and Evolutionary Biology.
• Mutualism (+, +) (between species) Increased density of species i increased per capitum
• Integrative Principles of Ecology ABIO 564 Spring 2012