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Signal Processing Techniques to Evaluate Surface Roughness of Weathered Rock Specimens
Weathering of rock surfaces results in an increase in the surface roughness of the rock. This surface can be assessed quantitatively using a number of statistical methods, typically granting a single-value measure of approximate roughness and, by extension, an approximate degree of weathering. In re...
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| creator | McGough, Mason Hudyma, Nick Harris, Alan Kreidl, O. Patrick Kopp, Brian |
| description | Weathering of rock surfaces results in an increase in the surface roughness of the rock. This surface can be assessed quantitatively using a number of statistical methods, typically granting a single-value measure of approximate roughness and, by extension, an approximate degree of weathering. In recent years the techniques developed by electrical and signal engineers for analyzing signals have been applied to this surface roughness characterization. Seven core samples of limestone rock were scanned and converted into linear profiles along the surface of the rock samples. The signal energy (E s ) and Z 2 , two single-value roughness measures, were calculated from these samples and Fourier and wavelet transforms were applied as well. The wavelet coefficients were then averaged, yielding a third single-value roughness measure. All three single-value roughness measures demonstrate remarkable agreement with one another with the exception of Z 2 , which estimates the roughness of one profile as slightly higher than two other profiles. This inconsistency appears to be due to an atypically high frequency content in that profile, exaggerating the measure of Z 2 . The wavelet transform technique proves to be very effective at locating sharp discontinuities along a rock at both low and high frequencies, promising better generalization to broader types of samples. |
| doi_str_mv | 10.1109/SoutheastCon42311.2019.9020450 |
| format | conference_proceeding |
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Patrick ; Kopp, Brian</creator><creatorcontrib>McGough, Mason ; Hudyma, Nick ; Harris, Alan ; Kreidl, O. Patrick ; Kopp, Brian</creatorcontrib><description>Weathering of rock surfaces results in an increase in the surface roughness of the rock. This surface can be assessed quantitatively using a number of statistical methods, typically granting a single-value measure of approximate roughness and, by extension, an approximate degree of weathering. In recent years the techniques developed by electrical and signal engineers for analyzing signals have been applied to this surface roughness characterization. Seven core samples of limestone rock were scanned and converted into linear profiles along the surface of the rock samples. The signal energy (E s ) and Z 2 , two single-value roughness measures, were calculated from these samples and Fourier and wavelet transforms were applied as well. The wavelet coefficients were then averaged, yielding a third single-value roughness measure. All three single-value roughness measures demonstrate remarkable agreement with one another with the exception of Z 2 , which estimates the roughness of one profile as slightly higher than two other profiles. This inconsistency appears to be due to an atypically high frequency content in that profile, exaggerating the measure of Z 2 . 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The wavelet coefficients were then averaged, yielding a third single-value roughness measure. All three single-value roughness measures demonstrate remarkable agreement with one another with the exception of Z 2 , which estimates the roughness of one profile as slightly higher than two other profiles. This inconsistency appears to be due to an atypically high frequency content in that profile, exaggerating the measure of Z 2 . The wavelet transform technique proves to be very effective at locating sharp discontinuities along a rock at both low and high frequencies, promising better generalization to broader types of samples.</description><subject>Measurement by laser beam</subject><subject>Rocks</subject><subject>Rough surfaces</subject><subject>Signal processing</subject><subject>Surface emitting lasers</subject><subject>Surface roughness</subject><subject>Surface treatment</subject><subject>wavelet analysis</subject><issn>1558-058X</issn><isbn>1728101379</isbn><isbn>9781728101378</isbn><fulltext>true</fulltext><rsrctype>conference_proceeding</rsrctype><creationdate>2019</creationdate><recordtype>conference_proceeding</recordtype><sourceid>6IE</sourceid><recordid>eNotkE1Lw0AYhFdBsK3-Ai978pa6737k4yihWqGgmPpxK8vm3WQ1zdZsIvjvXbGnGYaHYRhCroEtAVhxU_lpbFGHsfS95AJgyRkUy4JxJhU7IXPIeA4MRFackhkolSdM5e_nZB7CB_ujQM3Ia-WaXnf0afAGQ3B9Q7do2t59TRjo6OnqW3eTHpFW02C1Qfrsp6btI0u9pW-o44gB6xibT1od0Lg99uGCnFndBbw86oK83K225TrZPN4_lLebxHEmxkQIrrSQRitjMC5MeZoKxtFabqPVimeyBiOUrcFaXecKIK0xlSCik5lYkKv_XoeIu8Pg9nr42R0_EL9NQVUf</recordid><startdate>201904</startdate><enddate>201904</enddate><creator>McGough, Mason</creator><creator>Hudyma, Nick</creator><creator>Harris, Alan</creator><creator>Kreidl, O. 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Patrick</au><au>Kopp, Brian</au><format>book</format><genre>proceeding</genre><ristype>CONF</ristype><atitle>Signal Processing Techniques to Evaluate Surface Roughness of Weathered Rock Specimens</atitle><btitle>2019 SoutheastCon</btitle><stitle>SECON</stitle><date>2019-04</date><risdate>2019</risdate><spage>1</spage><epage>7</epage><pages>1-7</pages><eissn>1558-058X</eissn><eisbn>1728101379</eisbn><eisbn>9781728101378</eisbn><abstract>Weathering of rock surfaces results in an increase in the surface roughness of the rock. This surface can be assessed quantitatively using a number of statistical methods, typically granting a single-value measure of approximate roughness and, by extension, an approximate degree of weathering. In recent years the techniques developed by electrical and signal engineers for analyzing signals have been applied to this surface roughness characterization. Seven core samples of limestone rock were scanned and converted into linear profiles along the surface of the rock samples. The signal energy (E s ) and Z 2 , two single-value roughness measures, were calculated from these samples and Fourier and wavelet transforms were applied as well. The wavelet coefficients were then averaged, yielding a third single-value roughness measure. All three single-value roughness measures demonstrate remarkable agreement with one another with the exception of Z 2 , which estimates the roughness of one profile as slightly higher than two other profiles. This inconsistency appears to be due to an atypically high frequency content in that profile, exaggerating the measure of Z 2 . 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| fulltext | fulltext_linktorsrc |
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| ispartof | 2019 SoutheastCon, 2019, p.1-7 |
| issn | 1558-058X |
| language | eng |
| recordid | cdi_ieee_primary_9020450 |
| source | IEEE Xplore All Conference Series |
| subjects | Measurement by laser beam Rocks Rough surfaces Signal processing Surface emitting lasers Surface roughness Surface treatment wavelet analysis |
| title | Signal Processing Techniques to Evaluate Surface Roughness of Weathered Rock Specimens |
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