TY - GEN
T1 - Measure-Transformed Graphical Lasso
AU - Todros, Koby
AU - Routtenberg, Tirza
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025/1/1
Y1 - 2025/1/1
N2 - This paper tackles the problem of robust Gaussian graphical modeling in the presence of outliers. To this end, we propose a new robust variant of the GLASSO estimator, called measure-transformed (MT) GLASSO. This estimator operates by applying a transform to the probability measure of the data. The transform is generated by a non-negative data-weighting function, called MT-function. Specifically, we employ a Gaussian-Shaped MT-function, which effectively suppresses outliers and ensures transformation invariance of the nominal graph structure. Consequently, in MT-GLASSO, the standard sample covariance matrix is replaced with the empirical MT-covariance. The MT-GLASSO maintains the simplicity and computational efficiency of GLASSO. Furthermore, we propose a data-driven procedure to determine the scale parameter of the Gaussian MT-function, which controls the extent of outlier shrinkage. This procedure limits the Fisher-Information loss in the transform domain. The MT-GLASSO is illustrated in a simulation study highlighting its advantages over GLASSO and other robust extensions.
AB - This paper tackles the problem of robust Gaussian graphical modeling in the presence of outliers. To this end, we propose a new robust variant of the GLASSO estimator, called measure-transformed (MT) GLASSO. This estimator operates by applying a transform to the probability measure of the data. The transform is generated by a non-negative data-weighting function, called MT-function. Specifically, we employ a Gaussian-Shaped MT-function, which effectively suppresses outliers and ensures transformation invariance of the nominal graph structure. Consequently, in MT-GLASSO, the standard sample covariance matrix is replaced with the empirical MT-covariance. The MT-GLASSO maintains the simplicity and computational efficiency of GLASSO. Furthermore, we propose a data-driven procedure to determine the scale parameter of the Gaussian MT-function, which controls the extent of outlier shrinkage. This procedure limits the Fisher-Information loss in the transform domain. The MT-GLASSO is illustrated in a simulation study highlighting its advantages over GLASSO and other robust extensions.
KW - Estimation theory
KW - graphical models
KW - probability measure transform
KW - robust statistics
UR - https://www.scopus.com/pages/publications/105012159387
U2 - 10.1109/SSP64130.2025.11073401
DO - 10.1109/SSP64130.2025.11073401
M3 - Conference contribution
AN - SCOPUS:105012159387
T3 - IEEE Workshop on Statistical Signal Processing Proceedings
SP - 296
EP - 300
BT - 2025 IEEE Statistical Signal Processing Workshop, SSP 2025
PB - Institute of Electrical and Electronics Engineers
T2 - 2025 IEEE Statistical Signal Processing Workshop, SSP 2025
Y2 - 8 June 2025 through 11 June 2025
ER -