The Emergence of Edgar Morin's Complex Thinking.

Edgar Morin is more than 100 years old and has produced numerous original ideas. Complex Thinking is his approach to complexity and took almost thirty years to be written. He developed it based on many other thinkers but chiefly, we argue, on Wiener's Cybernetics, von Bertalanffy's General System Theory and Shannon's Information Theory.

Clock signal distribution with second order nodes: Design hints.

Despite being in use since the 1960's, clock distribution networks continue to be important, mainly since the digitalization of numerous electronic tasks, which demands precise time measures for synchronizing internal and external processes in computational and instrumentation applications. Designing clock distribution networks requires determination/estimation of the appropriate topologies and parameters that guarantee the mutual synchronization of the coupled oscillators. This problem has been largely studied in the telecommunications context, with digital hierarchies succeeding at providing precise multiplexing and switching, integrating services, and in the process, giving rise to a new era of communication.

Complexity engineering: New ideas for engineering design and engineering education.

This paper presents a theoretical approach to complexity engineering by considering the complex thinking framework proposed by Edgar Morin. The main foundations of this approach are an open system design, emergence, randomness inclusion, and Gödel incompleteness, which are contextualized using real-word instructive problems. Considering these concepts, several conjectures related to engineering activity and engineering education are presented taking several Brazilian catastrophes as counterexamples.

SIRSi compartmental model for COVID-19 pandemic with immunity loss.

The coronavirus disease 2019 (Covid-19) outbreak led the world to an unprecedented health and economic crisis. In an attempt to respond to this emergency, researchers worldwide are intensively studying the dynamics of the Covid-19 pandemic. In this study, a Susceptible - Infected - Removed - Sick (SIRSi) compartmental model is proposed, which is a modification of the classical Susceptible - Infected - Removed (SIR) model.

A dynamical model of fast cortical reorganization.

In this work we study the connection between some dynamic effects at the synaptic level and fast reorganization of cortical sensory maps. By using a biologically plausible computational model of the primary somatosensory system we obtained simulation results that can be used to relate the dynamics of the interactions of excitatory and inhibitory neurons to the process of somatotopic map reorganization immediately after peripheral lesion. The model consists of three regions integrated into a single structure: tactile receptors representing the glabrous surface of the hand, ventral posterior lateral nucleus of the thalamus and area 3b of the primary somatosensory cortex, reproducing the main aspects of the connectivity of these regions.