Discrete least-squares finite element methods
Brendan Keith, Socratis Petrides, Federico Fuentes, and Leszek, Demkowicz

TL;DR
This paper introduces a finite element method for boundary value problems that discretizes differential operators and a Riesz map, offering two approaches for solving the resulting overdetermined linear systems with distinct advantages.
Contribution
It presents a novel finite element methodology involving discretization of both the differential operator and Riesz map, along with detailed algorithms for solving the resulting overdetermined systems.
Findings
Normal equation approach is faster and requires less storage.
Orthogonalization reduces condition number and improves stability.
Method effectively solves Poisson's equation and linear acoustics problems.
Abstract
A finite element methodology for large classes of variational boundary value problems is defined which involves discretizing two linear operators: (1) the differential operator defining the spatial boundary value problem; and (2) a Riesz map on the test space. The resulting linear system is overdetermined. Two different approaches for solving the system are suggested (although others are discussed): (1) solving the associated normal equation with linear solvers for symmetric positive-definite systems (e.g. Cholesky factorization); and (2) solving the overdetermined system with orthogonalization algorithms (e.g. QR factorization). The finite element assembly algorithm for each of these approaches is described in detail. The normal equation approach is usually faster for direct solvers and requires less storage. The second approach reduces the condition number of the system by a power of…
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See pages 1-last of main.pdf
