This document discusses survey design and procedures for electrical resistivity surveys. It describes three common modes: 1) Sounding mode, where electrode spacing is varied to map resistivity with depth at fixed locations. 2) Profiling mode, where electrode spacing is fixed and the array is moved laterally to map lateral resistivity variations. 3) Profiling-sounding mode, which combines aspects of profiling and sounding modes. Common electrode arrays like Wenner and Schlumberger are described for each mode. Sounding and profiling modes are suited for mapping vertical and horizontal resistivity contrasts respectively.
Electrical resistivity a geophysical method and its applications in environm...Oluwaseun Odipe
The common use of Electrical resistivity methods in Environmental Health Science, i.e. safe water aquifer investigation (saline intrusion, groundwater investigation), pollution mapping, site selection (landfill, structures) etc
Electrical resistivity a geophysical method and its applications in environm...Oluwaseun Odipe
The common use of Electrical resistivity methods in Environmental Health Science, i.e. safe water aquifer investigation (saline intrusion, groundwater investigation), pollution mapping, site selection (landfill, structures) etc
Introduction
Petrophysic of the rocks
It is the study of the physical and chemical properties of the rocks related to the pores and fluid distribution
Porosity, is ratio between volume of void to the total voids of the rock.
Permeability, is ability of a porous material to allow fluids to pass through it.
Electric, most of the sedimentary rocks don’t have conductivity.
Radiation, clay rocks have 40K, radiate alpha ray.
Hardness, it depends on the cementing material and thickness of the sediments.
WELL LOGGING
The systematic recording of rock properties and it’s fluid contents in wells being drilled or produced to obtain various petrophysical parameters and characteristics of down hole sequences (G.E Archie 1950).
The measurement versus depth or time, or both, of one or more physical properties in a well.
These methods are particularly good when surface outcrops are not available, but a direct sample of the rock is needed to be sure of the lithology.
A wide range of physical parameters can be measured.
In some cases, the measurements are not direct, it require interpretation by analogy or by correlating values between two or more logs run in the same hole.
Provide information on lithology, boundaries of formations and stratigraphic correlation.
Determine Porosity, Permeability, water, oil and gas saturation.
Reservoir modeling and Structural studies… etc.
Types of Well Logging
Logs can be classified into several types under different category
Permeability and lithology Logs
Gamma Ray log
Self Potential [SP] log
Caliber log
Porosity Logs
Density log
Sonic log
Neutron log
Electrical Logs
Resistivity Log
For contact : omerupto3@gmail.com
It covers seismic method, gravity method, electromagnetic method, magnetic method and radiometric method. all these methods help in mineral exploration
The Lectures describes the Electrical method of Geophysical Prospecting in brief. SP surveying and Occurrence of Self potential and its application is discussed in brief.
This Lecture includes the Resistivity survey, field procedure, application advantage, limitaion, Apparant resistivity, VES (Vertical Electrical Sounding), Resistivity Profiling and IP Survey in brief.
Introduction
Petrophysic of the rocks
It is the study of the physical and chemical properties of the rocks related to the pores and fluid distribution
Porosity, is ratio between volume of void to the total voids of the rock.
Permeability, is ability of a porous material to allow fluids to pass through it.
Electric, most of the sedimentary rocks don’t have conductivity.
Radiation, clay rocks have 40K, radiate alpha ray.
Hardness, it depends on the cementing material and thickness of the sediments.
WELL LOGGING
The systematic recording of rock properties and it’s fluid contents in wells being drilled or produced to obtain various petrophysical parameters and characteristics of down hole sequences (G.E Archie 1950).
The measurement versus depth or time, or both, of one or more physical properties in a well.
These methods are particularly good when surface outcrops are not available, but a direct sample of the rock is needed to be sure of the lithology.
A wide range of physical parameters can be measured.
In some cases, the measurements are not direct, it require interpretation by analogy or by correlating values between two or more logs run in the same hole.
Provide information on lithology, boundaries of formations and stratigraphic correlation.
Determine Porosity, Permeability, water, oil and gas saturation.
Reservoir modeling and Structural studies… etc.
Types of Well Logging
Logs can be classified into several types under different category
Permeability and lithology Logs
Gamma Ray log
Self Potential [SP] log
Caliber log
Porosity Logs
Density log
Sonic log
Neutron log
Electrical Logs
Resistivity Log
For contact : omerupto3@gmail.com
It covers seismic method, gravity method, electromagnetic method, magnetic method and radiometric method. all these methods help in mineral exploration
The Lectures describes the Electrical method of Geophysical Prospecting in brief. SP surveying and Occurrence of Self potential and its application is discussed in brief.
This Lecture includes the Resistivity survey, field procedure, application advantage, limitaion, Apparant resistivity, VES (Vertical Electrical Sounding), Resistivity Profiling and IP Survey in brief.
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This Presentation tries to cover Beam forming, beam steering & beam with changes subtopic for RADAR systems.
This PPT was made for Internal Assessment seminar for 18ECOE07- Open Elective I- Introduction to Radar systems- 7th semester, Jain (Deemed-to-be) University, Bengaluru India by Chaitanya Shukla (19BTRAS051)
1. Subject 14: Survey design and procedure
Lecturer: Dr. Bakhtiar Q. Aziz
Objective: The student will learn how to make a complete scientific plan for a
resistivity survey in the field and how to select a suitable field design for a certain
problem. Two field procedures are explain to the students, profiling mode and
sounding mode.
Scientific contents
1- Vertical electrical sounding.
1- lateral profiling.
3- Profiling-sounding mode.
References
1. Applied and environmental geophysics, 1999, Sharma,V.,P.
2. Introduction to geophysical prospecting, 1988, Durbin, M. B.
3. www.Geophysics.net
4. www.hager-richter.com/resistivity.htm
5. www.geovision.com/PDF/M_Resistivity.pdf
3. C1 P1 P2 C2
6- Gradient Array a Surface
P0
C1 P1 P2 C2
½a ½a
7- Lee-partition Array a a Surface
C2 P2
a
C1 a P1 a
a
8- Square Array
4. Advantages and Disadvantages of Wenner and Schlumberger Arrays
The following table lists some of the strengths and weaknesses of
Schlumberger and Wenner sounding methods.
Schlumberger Wenner
Advantage Disadvantage Advantage Disadvantage
Need to move the two
potential electrodes only
for most readings. This All four electrodes, two current and
can significantly two potential must be moved to
decrease the time acquire each reading.
required to acquire a
sounding.
Because the potential Potential electrode
electrode spacing is small spacing increases as
compared to the current current electrode
electrode spacing, for large spacing increases.
current electrode spacings Less sensitive
very sensitive voltmeters are voltmeters are
required. required.
Because all electrodes are moved for
Because the potential
each reading, this method can be more
electrodes remain in
susceptible to near-surface, lateral,
fixed location, the
variations in resistivity. These near-
effects of near-surface
surface lateral variations could
lateral variations in
potentially be misinterpreted in terms
resistivity are reduced.
of depth variations in resistivity.
In general, interpretations
based on DC soundings will In general, interpretations based on
be limited to simple, DC soundings will be limited to simple,
horizontally layered horizontally layered structures.
structures.
5. Survey Design and Procedure
Survey design depends on the specific characteristics of the site and the objective of the
survey. The three most common modes of electrical resistivity surveying are profiling,
sounding, and profiling-sounding, each having its own specific purpose. If the purpose of
the survey is to map the depths and thickness of stratigraphic units, then the electrical
resistivity data should be collected in the sounding mode. Lateral electrical resistivity
contrasts, such as lithologic contacts, can best be mapped in the profiling mode. In
cases where the electrical resistivity is expected to vary both vertically and horizontally,
such as in contaminant plume mapping, the preferred mode is profile sounding.
1- Sounding Mode
As we've already shown, the resistivity method can detect variations in resistivity that
occur solely in depth. In fact, this method is most commonly applied to look for variations
in resistivity with depth. Surveys that are designed to determine resistivity variations with
depth above some fixed surface location are referred to as resistivity soundings. In these
experiments, electrode spacing is varied for each measurement. The center of the
electrode array, where the electrical potential is measured, however, remains fixed. An
example of a problem for which one might employ resistivity soundings is the
determination of the depth to water table
The two most common arrays for electrical resistivity surveying in the sounding mode
are the Schlumberger and Wenner arrays. Electrode geometry for both arrays is shown
in Figure below.
Increasing the separation of the outer current electrodes, thereby driving the currents
deeper into the subsurface increases the depth of exploration.
6. Wenner Sounding Schlumberger Sounding
VES-1 VES-1
a=1m AB/2=1.5, MN/2=0.5
a=2m AB/2=2, MN/2=0.5
a=3m AB/2=3, MN/2=0.5
a=4m AB/2=4, MN/2=0.5
a=5m AB/2=5, MN/2=0.5
AB/2=5, MN/2=1
Data Table
Data Table
a,m R ρa
AB/2 R ρa
1
1.5
2
2
3
3
4
4
ρa Field Curve ρa Field Curve
a,m AB/2
7. 2- Profiling Mode
The two most common arrays for electrical resistivity surveying in the profiling mode are
the Wenner and dipole-dipole arrays. The electrode geometry for the Wenner array is
the same as the sounding mode — the difference is that in profiling mode the entire
array is moved laterally along the profile while maintaining the potential and current
electrode separation distances.
The electrode geometry for the dipole-dipole array is shown in Figure below. In the
profiling mode, the distance between the potential and current dipoles (a dipole consists
of a pair of like electrodes) is maintained while the array is moved along the profile.
As was mentioned on the previous page, the data collected from resistivity soundings is
usually interpretable only for horizontally stratified structures. If you are employing
resistivity methods to find vertical structures, one would typically use resistivity profiles
instead of resistivity soundings.
As described previously, resistivity profiles are resistivity surveys in which the electrode
spacing is fixed for all readings. Apparent resistivity is computed for different electrode
center points as the electrode spread is moved. Usually the center point is moved along
the line of the electrodes, although this does not have to be the case. Shown below is a
geological structure involving a vertical boundary between a higher resistivity material to
the left and a lower resistivity material to the right. Below the geological model is the
apparent resistivity you would observe using a Wenner array as the array is moved from
left to right. Note that the distance shown along the bottom of this plot is the distance
between the vertical fault and the current electrode farthest to the left of the array.
8. Profiling by Wenner array
a= 5 m
1 2 3 4 5 6 Profile-1
1 2 3 4 5 6 Profile-2
1 2 3 4 5 6
Profile-3
Data Table
St. R ρa
1
2
3
4
ρa Field Curve
St. (Distance ,m)
9. 3- Profiling-Sounding Mode
As in the profiling mode, the Wenner and dipole-dipole arrays are the most common
arrays used in the profiling sounding mode. As the name implies, this mode is a
combination of the profiling and sounding modes.
In the Wenner array the typical field procedure is to collect the data in a succession of
profiles, each having a different electrode separation. The resulting data therefore
contains information about the lateral and vertical electrical resistivity variations.
(3) (2) (1)