Examining the Transition Networks of Secondary Special Educators: An Explanatory Sequential Mixed Methods Study

Successful outcomes for youth with disabilities require collaboration within and beyond the school system. Collaboration ideally includes a range of professionals across school systems, service systems, and communities coming together as part of a “transition network” to support the transition process. Using a quantitative survey of 509 secondary special educators and 25 semi-structured interviews, this explanatory sequential mixed methods study (a) examined the characteristics of transition networks (i.e., the social networks of secondary special educators), (b) identified variables associated with larger networks, and (c) explored educators’ interpretations of these associations. Quantitative analyses indicated that larger networks were associated with working at the high school level, supporting students with moderate/severe disabilities, increased years of experience, and greater knowledge about establishing collaborative partnerships. Interview analyses provided context for the quantitative results. These findings provide a deeper portrait of prevailing transition collaborations and have implications for educators charged with delivering high-quality transition programming.

Causal coupling inference from multivariate time series based on ordinal partition transition networks

Identifying causal relationships is a challenging yet crucial problem in many fields of science like epidemiology, climatology, ecology, genomics, economics and neuroscience, to mention only a few. Recent studies have demonstrated that ordinal partition transition networks (OPTNs) allow inferring the coupling direction between two dynamical systems. In this work, we generalize this concept to the study of the interactions among multiple dynamical systems and we propose a new method to detect causality in multivariate observational data. By applying this method to numerical simulations of coupled linear stochastic processes as well as two examples of interacting nonlinear dynamical systems (coupled Lorenz systems and a network of neural mass models), we demonstrate that our approach can reliably identify the direction of interactions and the associated coupling delays. Finally, we study real-world observational microelectrode array electrophysiology data from rodent brain slices to identify the causal coupling structures underlying epileptiform activity. Our results, both from simulations and real-world data, suggest that OPTNs can provide a complementary and robust approach to infer causal effect networks from multivariate observational data.

A Novel Measure Inspired by Lyapunov Exponents for the Characterization of Dynamics in State-Transition Networks

The combination of network sciences, nonlinear dynamics and time series analysis provides novel insights and analogies between the different approaches to complex systems. By combining the considerations behind the Lyapunov exponent of dynamical systems and the average entropy of transition probabilities for Markov chains, we introduce a network measure for characterizing the dynamics on state-transition networks with special focus on differentiating between chaotic and cyclic modes. One important property of this Lyapunov measure consists of its non-monotonous dependence on the cylicity of the dynamics. Motivated by providing proper use cases for studying the new measure, we also lay out a method for mapping time series to state transition networks by phase space coarse graining. Using both discrete time and continuous time dynamical systems the Lyapunov measure extracted from the corresponding state-transition networks exhibits similar behavior to that of the Lyapunov exponent. In addition, it demonstrates a strong sensitivity to boundary crisis suggesting applicability in predicting the collapse of chaos.