1,721,490 research outputs found
Replication Data for: Linear model and extensions
No full textR code and data for the book "Linear model and extensions
Replication data for "Principal stratification analysis using principal scores" by Peng Ding and Jiannan Lu
No full textThe paper is available at http://arxiv.org/pdf/1602.01196v1.pdf, and will appear in the Journal of the Royal Statistical Society, Series B
Supplementary materials for ``Bayesian causal inference: a critical review''
No full textSome background materials and R code for the paper: Li, F., Ding, P. and Mealli, F. (2023). Bayesian causal inference: a critical review. Philosophical Transactions of the Royal Society A, 381, 20220153
Replication Data for: Model-assisted analyses of cluster-randomized experiments
No full textR code and datasets for
“Model-assisted analyses of cluster-randomized experiments” by Su and Ding, which will appear in the Journal of the Royal Statistical Society, Series B
Replication data for "Principal stratification analysis using principal scores" by Peng Ding and Jiannan Lu
No full textThe paper is available at http://arxiv.org/pdf/1602.01196v1.pdf, and will appear in the Journal of the Royal Statistical Society, Series B
Replication Data for: A First Course in Causal Inference
No full texthttps://arxiv.org/pdf/2305.18793
It will also appear at Chapman & Hall
Replication Data for: A bracketing relationship between difference-in-differences and lagged-dependent-variable adjustment
No full textreplication R code and datasets for Examples 1 to 3 in the paper
Shock Waves
No full textWe discuss the physics of shock waves with special emphasis on the phenomena related to the field of nonlinear fiber optics. We first introduce the general
mechanism commonly known as gradient catastrophe and the related concept of classical shock waves. Then we proceed to discuss the possible regularizationmechanisms of the shock, and in particular the dispersive regularization, which is behind the formation of dispersive shock waves in fibers. We then discuss different possible scenarios that lead to observe the formation of dispersive shock waves in fibers, such as pulse propagation, four-wave mixing, and passive resonators, also showing that fibers allow for investigating the dispersive regime of classical problems related to the physics of shock such as the dam break problem and the propagation of Riemann waves.We also discuss the phase-matchingmechanism that induces the shock
to efficiently radiate resonant radiation in the normal dispersion regime. Throughout the text we refer to the mathematical models and the approaches that are employed to describe such phenomenona
Special issue on Advanced statistical modeling and causal inference with complex data for better decision making
No full text
- …
