We consider isogeometric discretizations of the Poisson model problem, focusing on high polynomial degrees and strong hierarchical refinements. We derive a posteriori error estimates by equilibrated fluxes, i.e, vector-valued mapped piecewise polynomials lying in the H(\div) space which appropriately approximate the desired divergence constraint. Our estimates are constant-free in the leading term, locally efficient, and robust with respect to the polynomial degree. They are also robust with respect to the number of hanging nodes arising in adaptive mesh refinement employing hierarchical B-splines.Two partitions of unity are designed, one with larger supports corresponding to the mapped splines, and one with small supports corresponding to ...
Highlights • A posteriori error estimation methodology for adaptive isogeometric analysis using LR B...
Introduced in [1], Isogeometric Analysis (IgA) has become widely accepted in academia and industry. ...
In this work, a method of goal-adaptive Isogeometric Analysis is proposed. We combine goal-oriented ...
We consider isogeometric discretizations of the Poisson model problem, focusing on high polynomial d...
We consider isogeometric discretizations of the Poisson model problem, focusing on high polynomial d...
We present a local construction of H(curl)-conforming piecewise polynomials satisfying a prescribed ...
We present novel H(div) and H1 liftings of given piecewise polynomials over a hierarchy of simplicia...
International audienceWe present equilibrated flux a posteriori error estimates in a unified setting...
Trimming consists of cutting away parts of a geometric domain, without reconstructing a global param...
For the Poisson problem in two dimensions, we consider the standard adaptive finite element loop sol...
In this work, we consider conforming finite element discretizations of arbitrary polynomial degree $...
The focus of this work is on the development of an error-driven isogeometric framework, capable of a...
Isogeometric analysis is a powerful paradigm which exploits the high smoothness of splines for the n...
In this thesis we will explore the possibilities of making a finite element solver for partial diffe...
Highlights • A posteriori error estimation methodology for adaptive isogeometric analysis using LR B...
Introduced in [1], Isogeometric Analysis (IgA) has become widely accepted in academia and industry. ...
In this work, a method of goal-adaptive Isogeometric Analysis is proposed. We combine goal-oriented ...
We consider isogeometric discretizations of the Poisson model problem, focusing on high polynomial d...
We consider isogeometric discretizations of the Poisson model problem, focusing on high polynomial d...
We present a local construction of H(curl)-conforming piecewise polynomials satisfying a prescribed ...
We present novel H(div) and H1 liftings of given piecewise polynomials over a hierarchy of simplicia...
International audienceWe present equilibrated flux a posteriori error estimates in a unified setting...
Trimming consists of cutting away parts of a geometric domain, without reconstructing a global param...
For the Poisson problem in two dimensions, we consider the standard adaptive finite element loop sol...
In this work, we consider conforming finite element discretizations of arbitrary polynomial degree $...
The focus of this work is on the development of an error-driven isogeometric framework, capable of a...
Isogeometric analysis is a powerful paradigm which exploits the high smoothness of splines for the n...
In this thesis we will explore the possibilities of making a finite element solver for partial diffe...
Highlights • A posteriori error estimation methodology for adaptive isogeometric analysis using LR B...
Introduced in [1], Isogeometric Analysis (IgA) has become widely accepted in academia and industry. ...
In this work, a method of goal-adaptive Isogeometric Analysis is proposed. We combine goal-oriented ...