King Fahd University of Petroleum & Minerals s3

King Fahd University of Petroleum & Minerals

Earth Sciences Department

GEOP 315

Seismic Exploration I

Final Exam

Student Name: Student ID#:

Instructions:

· Close your mobile

· This is a closed book & notes exam.

· Answer all the questions.

· Use figures and equations whenever appropriate.

· Define all your symbols.

Question 1 [25 points]:

Define the following briefly [5 points each]:

(a) The reflection coefficient at normal incidence.

(b) Head wave.

(d) Huygen’s principle.

(e) DMO.

(f) The requirements of a seismic source and how they are satisfied.

(g) The ghost multiple.

(h) Effect of geometrical spreading versus absorption on wave amplitude.

(i) The dilatation ().

Question 2 [15 points]:

Are the following statements true (T) or false (F) [3 points each]?

(a) sxz is a strain that is caused by a force parallel to the x-axis acting upon a surface perpendicular to the z-axis.

(b)
The P-wave velocity (a) in a fluid is given by: a = (l/r)1/2; where l and r are the Lame’s constant and density of the fluid.

(d) When fitting a hyperbola to the T-X curve of multiple layers, the fit is only good at Z/X<1, where Z is the depth and X is the offset.

(e) The most commonly used method for determining velocity in seismic exploration is the best-fit method.

(f) Calculate the reflection coefficient (R) for a P-wave propagating in water and incident the water-air interface. [5 points]

(g) The T-X curve of multiple layers is not a perfect hyperbola.

(h) The T-X curve of a single dipping layer is a hyperbola centered about the axis x = 0.

(i) The NMO correction increases with offset.

(j) The DMO is constant for the same layer.

(k) The velocity that results from fitting a straight line to the T2-X2 curve of multiple layers is called the average velocity.

Question 3 [15 points]:

Fill in the blanks with the correct answer (2.5 points each):

(a) Incoherent noise is ------in nature and cannot be followed across adjacent traces.

(b) The ideal geophone spacing to attenuate a horizontally traveling wave of wavelength l is ------.

(d) The ------is a layer near the surface, which is composed of loosely consolidated sediments.

(e) The limiting horizontal resolution on unmigrated sections is ------.

(f) A thin bed is that whose thickness is ------.

(g) a ------is the first reflection of the source wavelet from an interface.

(h) Incoherent noise is ------in nature and cannot be followed across adjacent traces.

(i) The limiting horizontal resolution on unmigrated sections is ------.

(j) The ------source usually generates a linear upsweep signal.

(k) In marine surveys, the ------generates seismic waves every time it expand or collapses.

(l) The ------is composed of a piezoelectric material.

(m) The main use of ------is to attenuate horizontally traveling ground rolls.

(n) A spread in which the source is in the center of regularly spaced geophone groups is called a ------spread.

(o) The ------is a layer near the surface, which is composed of loosely consolidated sediments.

(p) In a 3-D survey, a ------is the length over which sources are recorded without a crossline rollover.

Question 4 [20 points]

Draw a figure that shows the typical geometry of an orthogonal 3-D land survey and indicate the following (2.5 each):

(a) Receiver lines.

(b) Source lines.

(d) Crossline direction.

(e) Box.

(f) Bin.

(g) Patch.

(h) Swath.

Question 3 [30 points]:

The attached figure consists of several events:

(a) Define event A and compute its associated velocity [7 points].

(b) Define event B and compute its associated velocity [7 points].

(d) Use the above information to compute the critical angle qc [3 points]?

Question 4 [15 points]

(i) What are five important factors that control the design of a 3-D survey? [7.5 points]

(j) What are five important parameters that need to be set in a 3-D survey? [7.5 points]

Question 5 [25 points]:

Given the attached velocity model, compute the following:

(a) The interval zero-offset traveltime Dti of each reflector [5 points].

(b) The zero-offset traveltime to each reflector ti [3 points].

(d) Compute the depth to each reflector using the RMS velocities and zero-offset traveltimes [5 points].

(e) Compare the depths you computed in (e) with the real depths by computing the error in depth to each reflector [5 points].

(f) Is it justified, in this case, to use the RMS velocities and zero-offset traveltimes to compute the depths [2 points]?

Layer / Velocity (m/s) / Thickness (m) / Depth (m)
1 / 2000 / 200 / 200
2 / 3500 / 300 / 500
3 / 5000 / 500 / 1000

Question 3 [20 points]

(q) Define the NMO. Derive the approximate NMO formula. State at what condition the approximate formula is valid. [10 points]

(r) Given the following equation of a T-X curve that belongs to a single, homogeneous, horizontal layer: T2(X) = 0.25 + 1.610-7 X2. Calculate the layers velocity and thickness. [5 points]

(s) Given Figure 1 representing the T-X curve of a single, homogeneous, dipping layer. Find the layer’s dip, velocity, and thickness. [10 points]

Question 6 [30 points]:

Using the stacking chart in Figure 2, answer the following questions:

(a) What is the total number of receivers that the operator is using? [2.5 points]

(b) What is the total number of shots that the operator is using? [2.5 points]

(d) What is the type of spread being used? [2.5 points]

(e) What is the maximum number of CDP-fold that we can get with this geometry? [2.5 points]

(f) What is the CDP spacing? [2.5 points]

(g) In tables, sort the traces in:

(1) CDP domain, indicating fold for each CDP [8 points].

(2) Offset domain, indicating fold for each offset [7 points].

1 2 3 4 5 6 7 8 9 10

A O X X X X X

B O X X X X X

C O X X X X X

D O X X X X X

E O X X X X X

Spacing between stations = 40 m.

O stands for shot location.

X stands for receiver location.

Exam duration 50 minute

Good Luck

Ali Al-Ghamdi