Microcycle Spectral Estimation

<p>This thesis attempts to estimate the power spectral density of low frequency semiconductor noise over a range of 10 decades, from a microcycle (10<sup>-6</sup> cps) to 10 kilocycles (10<sup>+4</sup> cps). It is concluded that the behavior is more complex than a simpl...

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Main Author: Blakemore, David Jordan
Format: Others
Published: 1966
Online Access:https://thesis.library.caltech.edu/3573/1/Blakemore_dj_1966.pdf
Blakemore, David Jordan (1966) Microcycle Spectral Estimation. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/PH0Z-0431. https://resolver.caltech.edu/CaltechETD:etd-09172002-142819 <https://resolver.caltech.edu/CaltechETD:etd-09172002-142819>
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spelling ndltd-CALTECH-oai-thesis.library.caltech.edu-35732019-12-22T03:08:02Z Microcycle Spectral Estimation Blakemore, David Jordan <p>This thesis attempts to estimate the power spectral density of low frequency semiconductor noise over a range of 10 decades, from a microcycle (10<sup>-6</sup> cps) to 10 kilocycles (10<sup>+4</sup> cps). It is concluded that the behavior is more complex than a simple inverse proportionality to frequency. The spectrum is approximately 1/f in the region around 100 cps and changes gradually to 1/f<sup>2</sup> as the frequency decreases to the microcycle region. These spectra represent the noise properties of the first stage transistors of a grounded input dc differential amplifier. The estimated spectra at very low frequencies still reflect strong temperature influences.</p> <p>In order to obtain these measurements it was necessary to control the temperature environment of the noise source. This was accomplished first by passive attenuation and later by active control. The noise source was placed in a circulating oil bath whose temperature was sensed electrically and controlled to a .001° C range. In conjunction with the temperature control activity the power spectral density of room temperature variations was estimated in the frequency range from .1 cps down to 5 x 10<sup>-8</sup> cps. Other spectra of interest estimated over the low frequency range were for line voltage amplitude fluctuations and operational amplifier drift. A brief description of the equipment constructed to obtain sample functions of the noise processes is included.</p> <p>The analytical portion of this work is concerned with the mathematical techniques employed in obtaining power spectral density estimates. The basic scheme employed is that of Blackman and Tukey which consists of estimating the auto-correlation function and Fourier transforming the result. A formula is developed for calculating the variance of the spectral estimator actually employed in the computations. The bias and variability are presented for the estimator when estimating a spectra containing a spectral line. A confidence interval approach to the variability of the spectral estimator is examined. A confidence interval which depends only on the data is constructed around the spectral density estimate. A technique for utilizing the available knowledge concerning the expected variability of the spectral estimate is developed. The result is formulated in terms of a maximum liklihood estimator for the average spectral density when several independent estimates are available. Some possible sources of low frequency bias in the spectral estimate are considered in detail. Among these are the effect of mean removal and certain deterministic disturbances such as steps. Prewhitening for 1/f and 1/f<sup>2</sup> spectra is examined and shown to lead to very great improvement in the spectral estimate. Some suggestions as to more efficient methods of spectral estimation data collection and processing are offered.</p> 1966 Thesis NonPeerReviewed application/pdf https://thesis.library.caltech.edu/3573/1/Blakemore_dj_1966.pdf https://resolver.caltech.edu/CaltechETD:etd-09172002-142819 Blakemore, David Jordan (1966) Microcycle Spectral Estimation. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/PH0Z-0431. https://resolver.caltech.edu/CaltechETD:etd-09172002-142819 <https://resolver.caltech.edu/CaltechETD:etd-09172002-142819> https://thesis.library.caltech.edu/3573/
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format Others
sources NDLTD
description <p>This thesis attempts to estimate the power spectral density of low frequency semiconductor noise over a range of 10 decades, from a microcycle (10<sup>-6</sup> cps) to 10 kilocycles (10<sup>+4</sup> cps). It is concluded that the behavior is more complex than a simple inverse proportionality to frequency. The spectrum is approximately 1/f in the region around 100 cps and changes gradually to 1/f<sup>2</sup> as the frequency decreases to the microcycle region. These spectra represent the noise properties of the first stage transistors of a grounded input dc differential amplifier. The estimated spectra at very low frequencies still reflect strong temperature influences.</p> <p>In order to obtain these measurements it was necessary to control the temperature environment of the noise source. This was accomplished first by passive attenuation and later by active control. The noise source was placed in a circulating oil bath whose temperature was sensed electrically and controlled to a .001° C range. In conjunction with the temperature control activity the power spectral density of room temperature variations was estimated in the frequency range from .1 cps down to 5 x 10<sup>-8</sup> cps. Other spectra of interest estimated over the low frequency range were for line voltage amplitude fluctuations and operational amplifier drift. A brief description of the equipment constructed to obtain sample functions of the noise processes is included.</p> <p>The analytical portion of this work is concerned with the mathematical techniques employed in obtaining power spectral density estimates. The basic scheme employed is that of Blackman and Tukey which consists of estimating the auto-correlation function and Fourier transforming the result. A formula is developed for calculating the variance of the spectral estimator actually employed in the computations. The bias and variability are presented for the estimator when estimating a spectra containing a spectral line. A confidence interval approach to the variability of the spectral estimator is examined. A confidence interval which depends only on the data is constructed around the spectral density estimate. A technique for utilizing the available knowledge concerning the expected variability of the spectral estimate is developed. The result is formulated in terms of a maximum liklihood estimator for the average spectral density when several independent estimates are available. Some possible sources of low frequency bias in the spectral estimate are considered in detail. Among these are the effect of mean removal and certain deterministic disturbances such as steps. Prewhitening for 1/f and 1/f<sup>2</sup> spectra is examined and shown to lead to very great improvement in the spectral estimate. Some suggestions as to more efficient methods of spectral estimation data collection and processing are offered.</p>
author Blakemore, David Jordan
spellingShingle Blakemore, David Jordan
Microcycle Spectral Estimation
author_facet Blakemore, David Jordan
author_sort Blakemore, David Jordan
title Microcycle Spectral Estimation
title_short Microcycle Spectral Estimation
title_full Microcycle Spectral Estimation
title_fullStr Microcycle Spectral Estimation
title_full_unstemmed Microcycle Spectral Estimation
title_sort microcycle spectral estimation
publishDate 1966
url https://thesis.library.caltech.edu/3573/1/Blakemore_dj_1966.pdf
Blakemore, David Jordan (1966) Microcycle Spectral Estimation. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/PH0Z-0431. https://resolver.caltech.edu/CaltechETD:etd-09172002-142819 <https://resolver.caltech.edu/CaltechETD:etd-09172002-142819>
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