Your search keyword '"Campos, Paulo R A"' showing total 13 results

1. Evolving division of labor in a response threshold model

Author

Fontanari, José F., de Oliveira, Viviane M., and Campos, Paulo R. A.

Subjects

Quantitative Biology - Populations and Evolution, Nonlinear Sciences - Adaptation and Self-Organizing Systems, Nonlinear Sciences - Chaotic Dynamics

Abstract

The response threshold model explains the emergence of division of labor (i.e., task specialization) in an unstructured population by assuming that the individuals have different propensities to work on different tasks. The incentive to attend to a particular task increases when the task is left unattended and decreases when individuals work on it. Here we derive mean-field equations for the stimulus dynamics and show that they exhibit complex attractors through period-doubling bifurcation cascades when the noise disrupting the thresholds is small. In addition, we show how the fixed threshold can be set to ensure specialization in both the transient and equilibrium regimes of the stimulus dynamics. However, a complete explanation of the emergence of division of labor requires that we address the question of where the threshold variation comes from, starting from a homogeneous population. We then study a structured population scenario, where the population is divided into a large number of independent groups of equal size, and the fitness of a group is proportional to the weighted mean work performed on the tasks during a fixed period of time. Using a winner-take-all strategy to model group competition and assuming an initial homogeneous metapopulation, we find that a substantial fraction of workers specialize in each task, without the need to penalize task switching.

Published

2023

2. The role of epistasis in evolutionary rescue

Author

Freitas, Osmar and Campos, Paulo R. A.

Published

2024

3. An entropy-stable updated reference Lagrangian smoothed particle hydrodynamics algorithm for thermo-elasticity and thermo-visco-plasticity

Author

Lee, Chun Hean, Refachinho de Campos, Paulo R., Gil, Antonio J., Giacomini, Matteo, and Bonet, Javier

Published

2023

4. A novel Arbitrary Lagrangian Eulerian Smooth Particle Hydrodynamics algorithm for nonlinear solid dynamics

Author

Lee, Chun Hean, Gil, Antonio J., Refachinho de Campos, Paulo R., Bonet, Javier, Jaugielavičius, Tadas, Joshi, Shreyas, and Wood, Clare

Published

2024

5. A New Updated Reference Lagrangian Smooth Particle Hydrodynamics algorithm for isothermal elasticity and elasto-plasticity

Author

de Campos, Paulo R. Refachinho, Gil, Antonio J., Lee, Chun Hean, Giacomini, Matteo, and Bonet, Javier

Published

2022

6. Understanding Evolutionary Rescue and Parallelism in Response to Environmental Stress

Author

Freitas, Osmar, primary and Campos, Paulo R A, additional

Published

2024

7. Evolutionary rescue on genotypic fitness landscapes

Author

Wahl, L. M., primary and Campos, Paulo R. A., additional

Published

2023

8. Modeling and Control of a Flexible Electric Resistance Heater Coupled to a Steel Plate

Author

de Campos, Paulo R. Brero, Ruzyk, Matheus J. da Silva, Castaldo, Fernando, and dos Reis, Diego Dias

Abstract

Polyimide films have unique characteristics and are used to build versatile and resistant heaters that are adequate for applications in diverse areas. Their flexibility allows them to take multiple shapes but may result in intricate mathematical modeling. In this paper, a heater with flexible resistance coupled to a steel plate is modeled and compared with empirical measurements. The theoretical analysis of the system's behavior begins with determining differential equations from the energy balance. The resulting non-linear systems are submitted to a linearization process at an operating point. Transfer functions are obtained from linearized differential equations. In the experimental section, a power step is applied to the flexible resistance to plot the output temperature in a graph, where the heater's empirical parameters are identified. Theoretical and practical values are compared, proving the assertiveness of the models. Finally, a control system is projected and tested to demonstrate a practical application.

Published

2024

9. Phenotypic evolution as an Ornstein-Uhlenbeck process: The effect of environmental variation and phenotypic plasticity

Author

de Souza Silva, Clécio C., primary, Cirne, Diego, additional, Freitas, Osmar, additional, and Campos, Paulo R. A., additional

Published

2023

10. Modeling and control of a flexible electric resistance heater coupled to a steel plate

Author

de Campos, Paulo R. Brero, primary, Ruzyk, Matheus J. da Silva, additional, Castaldo, Fernando, additional, and Dias, Diego, additional

Published

2023

11. Rate of environmental variation impacts the predictability in evolution

Author

Cirne, Diego, primary and Campos, Paulo R. A., additional

Published

2022

12. Resource-based modelling approach to studying evolutionary rescue.

Author

Oliveira VM and Campos PRA

Subjects

Extinction, Biological, Population Density, Biological Evolution, Models, Biological

Abstract

In this paper, we present an in-depth investigation into the dynamics of evolutionary rescue using a resource-based modelling approach. Utilizing classical consumer-resource models, we aim to understand how species can adapt to abrupt environmental changes that alter the availability of substitutable resources. Through both analytical solutions and simulation-based techniques, we explore the conditions under which populations can recover from critical sizes and avoid extinction. Our findings highlight the importance of minimum viable population sizes, mutation rates, and the adaptive capacity of metabolic strategies in influencing population resilience. We demonstrate that while increased mutation rates can facilitate faster recovery by enabling populations to evolve new metabolic strategies suited to the altered resource landscape, populations starting with smaller sizes or facing severe reductions in resource availability are more susceptible to extinction. This study offers valuable insights into the interplay between ecological dynamics and evolutionary mechanisms, providing a comprehensive framework for predicting population persistence and informing conservation strategies under changing environmental conditions.

Published

2024

13. Patch biogeography under intermittent barriers: macroevolutionary consequences of microevolutionary processes.

Author

Freitas O, Campos PRA, and Araujo SBL

Abstract

The processes that generate biodiversity start on a microevolutionary scale, where each individual's history can impact the species' history. This manuscript presents a theoretical study that examines the macroevolutionary patterns that emerge from the microevolutionary dynamics of populations inhabiting two patches. The model is neutral, meaning that neither survival nor reproduction depends on a fixed genotype, yet individuals must have minimal genetic similarity to reproduce. We used historical sea level oscillation over the past 800 thousand years to hypothesize periods when individuals could migrate from one patch to another. In our study, we keep track of each speciation and extinction event, build the complete and extant phylogenies, and characterize the macroevolutionary patterns regarding phylogeny balance, acceleration of speciation, and crown age. We also evaluate ecological patterns: richness, beta diversity, and species distribution symmetry. The balance of the complete phylogeny can be a sign of the speciation mode, contrasting speciation induced by migration and isolation (vicariance). The acceleration of the speciation process is also affected by the geographical barriers and the duration of the isolation period, with high isolation times leading to accelerated speciation. We report the correlation between ecological and macroevolutionary patterns and show it decreases with the time spent in isolation. We discuss, in light of our results, the challenge of integrating present-time community ecology with macroevolutionary patterns., (© The Author(s) 2024. Published by Oxford University Press on behalf of the European Society of Evolutionary Biology. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2024