Title :
Principal Component Compression Method for Covariance Matrices Used for Uncertainty Propagation
Author :
Humphreys, David A. ; Harris, Peter M. ; Rodriguez-Higuero, Manuel ; Mubarak, Faisal Ali ; Dongsheng Zhao ; Ojasalo, Kari
Author_Institution :
Nat. Phys. Lab., Teddington, UK
Abstract :
We investigate a principal component analysis approach for compressing the covariance matrices derived from real-time and sampling oscilloscope measurements. The objective of reducing the data storage requirements to scale proportional to the trace length n rather than n2 is achieved, making the approach practical for representing results and uncertainties in either the time or frequency domain. Simulation results indicate that the covariance matrices can be represented in a compact form with negligible error. Mathematical manipulation of the compressed matrix can be achieved without the need to reconstruct the full covariance matrix. We have demonstrated compression of data sets containing up to 10000 complex frequency components.
Keywords :
covariance matrices; digital storage oscilloscopes; measurement uncertainty; principal component analysis; signal sampling; time-frequency analysis; complex frequency components; compressed matrix; covariance matrix; data storage requirement reduction; frequency domain analysis; measurement uncertainty propagation; principal component analysis; real-time measurement; sampling oscilloscope measurement; time domain analysis; Covariance matrices; Frequency-domain analysis; Instruments; Measurement uncertainty; Time-domain analysis; Uncertainty; Covariance matrix; Fourier transforms; frequency-domain measurements; measurement uncertainty; principal component analysis (PCA); time-domain measurements; timebase drift correction; timing jitter; uncertainty propagation;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
DOI :
10.1109/TIM.2014.2340640
