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Experimental studies of electromagnetic signals to enhance radio imaging method (RIM).

Record Type:	Electronic resources : Monograph/item
Title/Author:	Experimental studies of electromagnetic signals to enhance radio imaging method (RIM)./
Author:	Monaghan, William D.
Description:	115 p.
Notes:	Source: Masters Abstracts International, Volume: 46-04, page: 2297.
Contained By:	Masters Abstracts International46-04.
Subject:	Engineering, Mining. -
Online resource:	http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=1451919
ISBN:	9780549464914

Experimental studies of electromagnetic signals to enhance radio imaging method (RIM).
Monaghan, William D.

Experimental studies of electromagnetic signals to enhance radio imaging method (RIM). - 115 p.

Source: Masters Abstracts International, Volume: 46-04, page: 2297.

Thesis (M.S.Min.E.)--West Virginia University, 2007.

Safety and production of coal mining operations could be greatly affected by geologic anomalies such as faults, sandstone intrusions, dykes, fracture zones, sudden thinning and severe undulation of the coal seam. Since most of these geologic anomalies in coal seams effect the attenuation rate of electromagnetic signal that passes through them, the radio imaging method (RIM), using a signal in the kilohertz range, is capable of locating the zones of geologic anomalies in underground coal mines with the help of tomographic reconstruction programs. RIM technology is a promising geophysical tool for exploring the geologic anomalies ahead of modern longwall faces, which are normally wider than 1,000 ft. When multiple geologic anomalies co-exist in an area, it is very difficult for RIM technology to differentiate the contributions of each individual anomalous factor. Other problems with RIM technology are the angular spreading and moisture content is not taken into consideration of the surveyed area. To increase the accuracy of RIM technology, spatial spreading testing and a scaled physical model were employed to investigate the capabilities and limitations of RIM technology. To simulate the RIM technology, a Ground Penetration RADAR (GPR) system was modified and a higher frequency signal was used in the scaled physical model. One of the problems using the GPR was that data collected was represented in counts and formulae had to be developed in order to convert the data into volts. Laboratory testing was conducted to assure proper similarities between the actual longwall panel and the scaled physical model. These model tests were done to gain a better quantitative understanding of the propagation of EM signals in the physical model. The testing procedure and data results are presented and quantified.

ISBN: 9780549464914Subjects--Topical Terms:

1035560
Engineering, Mining.

Experimental studies of electromagnetic signals to enhance radio imaging method (RIM).
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100 1 $a Monaghan, William D. $3 1035567
245 1 0 $a Experimental studies of electromagnetic signals to enhance radio imaging method (RIM).
300 $a 115 p.
500 $a Source: Masters Abstracts International, Volume: 46-04, page: 2297.
502 $a Thesis (M.S.Min.E.)--West Virginia University, 2007.
520 $a Safety and production of coal mining operations could be greatly affected by geologic anomalies such as faults, sandstone intrusions, dykes, fracture zones, sudden thinning and severe undulation of the coal seam. Since most of these geologic anomalies in coal seams effect the attenuation rate of electromagnetic signal that passes through them, the radio imaging method (RIM), using a signal in the kilohertz range, is capable of locating the zones of geologic anomalies in underground coal mines with the help of tomographic reconstruction programs. RIM technology is a promising geophysical tool for exploring the geologic anomalies ahead of modern longwall faces, which are normally wider than 1,000 ft. When multiple geologic anomalies co-exist in an area, it is very difficult for RIM technology to differentiate the contributions of each individual anomalous factor. Other problems with RIM technology are the angular spreading and moisture content is not taken into consideration of the surveyed area. To increase the accuracy of RIM technology, spatial spreading testing and a scaled physical model were employed to investigate the capabilities and limitations of RIM technology. To simulate the RIM technology, a Ground Penetration RADAR (GPR) system was modified and a higher frequency signal was used in the scaled physical model. One of the problems using the GPR was that data collected was represented in counts and formulae had to be developed in order to convert the data into volts. Laboratory testing was conducted to assure proper similarities between the actual longwall panel and the scaled physical model. These model tests were done to gain a better quantitative understanding of the propagation of EM signals in the physical model. The testing procedure and data results are presented and quantified.
590 $a School code: 0256.
650 4 $a Engineering, Mining. $3 1035560
650 4 $a Geotechnology. $3 1018558
690 $a 0428
690 $a 0551
710 2 $a West Virginia University. $3 1017532
773 0 $t Masters Abstracts International $g 46-04.
790 $a 0256
791 $a M.S.Min.E.
792 $a 2007
856 4 0 $u http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=1451919