1. Needs to be more interactive Radar Methods - An Overview
Environmental and Exploration Geophysics II
Hand out sections and have them interpret/identify example GPR sections. Even with the review of resolution concepts, we finished in one hour
Radar Methods - An Overview
tom.h.wilson
Department of Geology and Geography
West Virginia University
Morgantown, WV

2. The radar band is loosely taken to extend from approximately 0
The radar band is loosely taken to extend from approximately 0.1cm to 100cm. The microwave region is often used for surface imaging from airborne or satellite platform.

3. Radar image of the earth’s surface at 5.4cm or 20 GHz.

4. Ground penetrating radar (GPR) systems often operate in the tens of MHz to GHz region of the spectrum.
25MHz = 12m wavelength (40ns)
50MHz = 6m (20ns)
100MHz = 3m (10ns)
1GHz = 0.3m (1ns)
Times in nanoseconds represent the time it takes light to travel through 1 wavelength in a vacuum.

5. Visual wavelength image
Shuttle Imaging Radar - SIR A
 ~ 25cm
Sabins, 1996

6. Sabins, 1996

7. dry sand penetration depth of ~ 1.25m
0.25 meter wavelength, 1.2 GHz
dry sand penetration depth of ~ 1.25m
Sabins, 1996

8. Ground Surveys
GPR bistatic and monostatic transmitter-receiver configurations. Note similarity to coincident source-receiver and offset source receiver configurations discussed in the context of seismic methods
Daniels, J., 1989

9. Spectral and temporal characteristics of the GPR wavelet.
Sensors & Software Inc. - Ekko Updates

10. As with seismic data, reflection arrival times are 2-way times and depth equals two-way time x average velocity.
Velocity in air is approximately velocity of light in a vacuum - c.
c = 3 x 108 m/sec
= 9.84 x 108 f/s
or approximately 1 foot per nanosecond. 1 nanosecond is 10-9th seconds.
Thinking in terms of two-way times, it takes 2ns to travel 1 ft.

11. In general the velocity of the radar wave is defined as
where c is the velocity of light in a vacuum (or air), and r is the electric permitivity of the material through which the radar wave travels.
Examples of r (see Daniels) are
81 for water
6 for unsaturated sand
20 for saturated sand
The presence of water has a significant effect on velocity.

12. Typical velocities
c ~ 1ft/ns in air
v ~ 1/2 to 1/3rd ft/ns in unsaturated sand
v ~ 1/3rd to 1/5th ft/ns in saturated sand
 is proportional to conductivity  - materials of relatively high conductivity have slower velocity than less conductive materials.

13. Daniels makes note of an equation which specifies how the electric field will respond to varying conditions of conductivity () and permitivity ().
Daniels goes on to note, specifically that the ratio
determines whether the material behaves primarily as a conductor or as a dielectric

14. where
In low-loss materials P ~ 0 and the speed of the radar waves is
As implied, low loss materials are also low conductivity () materials.

15. In our discussions of seismic we recognized absorption as an important process affecting the ability of the seismic wave to penetrate beneath the earth’s surface. High attenuation coefficient  produces rapid decay of seismic wave amplitude with distance traveled (r).
The same process controls the ability of electromagnetic waves to penetrate beneath the earth’s surface. The expression controlling attenuation is a function of several quantities, the most important of which are conductivity and permitivity.

16. Attenuation of electromagnetic waves is controlled by the propagation factor which has real and imaginary parts.
The real part  (the attenuation coefficient) illustrates the influence of permitivity and conductivity on absorption.
Note in this equation that increases of  translate into increased attenuation. Also note that increases of angular frequency (=2f) will increase attenuation.

17. The role of the attenuation coefficient  shows up clearly in the bistatic radar equation.
P is power, A is area and G is gain. The  in this equation refers to scattering cross section.
You’ll note some similarities between this equation and the one we derived in class for seismic waves.

18. On page 96 of Daniels paper there is some discussion of velocity determination. Reference is made to use of the diffraction response from an object at known depth. If the depth is known then the velocity is just depth divided by one-half the arrival time at the diffraction apex.
If the depth were not known, how else might you determine velocity from the appearance of the diffraction event?

22. Average Velocity = 1/2 the reciprocal of the slope

23. Sensors & Software Inc. - Ekko Updates

24. Critical refraction Direct arrival Reflection hyperbola
The characteristics of a common midpoint gather of GPR records looks very similar to those for seismic data.
Smith and Jol, 1995

25. Diffraction and normal incidence reflection response
Daniels, J., 1989

26. GPR diffractions
Daniels, J., 1989

27. Thinning layer response and resolution considerations.
Daniels, J., 1989

28. Horizontal Resolution: The Fresnel Zone

29. The Fresnel Zone Radius Rf
An approximation

30. Topographic variations must also be compensated for.
Daniels, J., 1989

31. GPR data is often collected by pulling the GPR unit across the surface
GPR data is often collected by pulling the GPR unit across the surface. Subsurface scans are made at regular intervals, but since the unit is often pulled at varying speeds across the surface, the records are adjusted to portray constant spacing between records. This process s referred to as rubbersheeting.
Daniels, J., 1989

32. Spectral and temporal characteristics of the GPR wavelet.
Sensors & Software Inc. - Ekko Updates

33. Smith and Jol, 1995, AG

34. Smith and Jol, 1995, AG

35. Comparison of the 25MHz and 100 MHz records
Smith and Jol, 1995, AG

36. Smith and Jol, 1995, AG

37. Sensors & Software Inc. - Ekko Updates

38. Noise corrupts GPR as well as seismic data
Noise corrupts GPR as well as seismic data. GPR sources are quite different.
Daniels, J., 1989

39. In the acquisition of GPR data one must worry about overhead reflections.
Daniels, J., 1989

40. …. and tree branches!
Daniels, J., 1989

41. The abrupt discontinuity of velocity associated with the house basement produces a nice diffraction.
Daniels, J., 1989

42. Sensors & Software Inc. - Ekko Updates
GPR unit
Sensors & Software Inc. - Ekko Updates

43. Sensors & Software Inc. - Ekko Updates

44. Terrain Conductivity Landfill Magnetic Field
Switzerland, glacial sediments
Green et al., 1999, LE

45. Ground Penetrating Radar data on and off the site
Green et al., 1999, LE

46. Time slice map from 3D data volume of radar data
Time slice map from 3D data volume of radar data. This is a surface of equal travel time. Disruptions in the reflection pattern are associated with the waste pit.
Green et al., 1999, LE

47. Bright red areas define the location of the landfill; the orange objects represent gravel bodies.
The brownish-pink lobes are high reflectivity objects of unknown origin.
The view at bottom profiles the underside of the landfill and gravel bodies.
Green et al., 1999, LE

48. Some general information about cost and effectiveness of various geophysical methods,
Green et al., 1999, LE

49. Sensors & Software Inc. - Ekko Updates

50. Sensors & Software Inc. - Ekko Updates

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52. Sensors & Software Inc. - Ekko Updates

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57. Sensors & Software Inc. - Noggin Notes

58. Sensors & Software Inc. - Ekko Updates

59. Sternberg and McGill, 1995, AG

60. Sensors & Software Inc. - Noggin Notes

61. Sternberg and McGill, 1995, AG

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64. Sensors & Software Inc. - Ekko Updates

65. High Resolution Imaging of Vadose Zone Transport using Crosswell Radar and Seismic Methods
Ernest L. Majer, Kenneth H. Williams, John E. Peterson, and Thomas M. Daley - Lawrence Berkley Labs

66. Geophysical surveys on the Scarcelli Vault of St
Geophysical surveys on the Scarcelli Vault of St. John’s Baptistery in Florence Italy
Carderelli et al., 2001

67. Dec. 3rd - Exploration Project Presentations
Dec. 5th, Term Report Presentations