TY - GEN
T1 - Reconstructing high-dimensional Hilbert-valued functions via compressed sensing
AU - Dexter, Nick
AU - Tran, Hoang
AU - Webster, Clayton
N1 - Publisher Copyright:
© 2019 IEEE.
PY - 2019/7
Y1 - 2019/7
N2 - We present and analyze a novel sparse polynomial technique for approximating high-dimensional Hilbert-valued functions, with application to parameterized partial differential equations (PDEs) with deterministic and stochastic inputs. Our theoretical framework treats the function approximation problem as a joint sparse recovery problem, where the set of jointly sparse vectors is possibly infinite. To achieve the simultaneous reconstruction of Hilbert-valued functions in both parametric domain and Hilbert space, we propose a novel mixed-norm based ℓ1 regularization method that exploits both energy and sparsity. Our approach requires extensions of concepts such as the restricted isometry and null space properties, allowing us to prove recovery guarantees for sparse Hilbert-valued function reconstruction. We complement the enclosed theory with an algorithm for Hilbert-valued recovery, based on standard forward-backward algorithm, meanwhile establishing its strong convergence in the considered infinite-dimensional setting. Finally, we demonstrate the minimal sample complexity requirements of our approach, relative to other popular methods, with numerical experiments approximating the solutions of high-dimensional parameterized elliptic PDEs.
AB - We present and analyze a novel sparse polynomial technique for approximating high-dimensional Hilbert-valued functions, with application to parameterized partial differential equations (PDEs) with deterministic and stochastic inputs. Our theoretical framework treats the function approximation problem as a joint sparse recovery problem, where the set of jointly sparse vectors is possibly infinite. To achieve the simultaneous reconstruction of Hilbert-valued functions in both parametric domain and Hilbert space, we propose a novel mixed-norm based ℓ1 regularization method that exploits both energy and sparsity. Our approach requires extensions of concepts such as the restricted isometry and null space properties, allowing us to prove recovery guarantees for sparse Hilbert-valued function reconstruction. We complement the enclosed theory with an algorithm for Hilbert-valued recovery, based on standard forward-backward algorithm, meanwhile establishing its strong convergence in the considered infinite-dimensional setting. Finally, we demonstrate the minimal sample complexity requirements of our approach, relative to other popular methods, with numerical experiments approximating the solutions of high-dimensional parameterized elliptic PDEs.
KW - High-dimensional approximation
KW - Hilbert-valued functions
KW - bounded orthonormal systems
KW - compressed sensing
KW - forward-backward iterations
KW - parametric PDEs
UR - http://www.scopus.com/inward/record.url?scp=85082861008&partnerID=8YFLogxK
U2 - 10.1109/SampTA45681.2019.9030842
DO - 10.1109/SampTA45681.2019.9030842
M3 - Conference contribution
AN - SCOPUS:85082861008
T3 - 2019 13th International Conference on Sampling Theory and Applications, SampTA 2019
BT - 2019 13th International Conference on Sampling Theory and Applications, SampTA 2019
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 13th International Conference on Sampling Theory and Applications, SampTA 2019
Y2 - 8 July 2019 through 12 July 2019
ER -