Introduction to Phased Array Using the OmniScan MX2 - Part Three

OmniScan MX2 Training Program
Introduction to Phased Array Using the OmniScan MX2

Part 3
Please send questions and comments to: PhasedArraySupport@olympusndt.com

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Overview
Ø  Supporting documentation for the training program comes primarily from the MX2
software manuals and the Olympus reference manuals below.
Ø  Modern phased array systems like the MX2 do not require an advanced knowledge
of mathematics or acoustic theory and the training program focuses on practical
explanations and real world application examples for the working inspector.
Ø  Supporting theory, mathematical formulas, and more advanced PA concepts can be
found in the books below available from the ONDT web site.
Ø  These manuals can be downloaded at http://www.olympus-ims.com

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Review

3

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Velocity
Ø  The velocities of the wedge and component material are two of many parameters
that must be known to the part and group set up wizard prior to the formation of the
focal laws.
Ø  No velocity correction can be made without recreating the focal laws.
Ø  Like conventional UT, velocity is directly related to beam angle. (Snell’s law)
When the velocity of the material or wedge is other than what was input into the
group set up wizard the result is that the beam angle is not what it is supposed to
be and cannot be corrected. (The 70 degree beam is really 68 degrees)
Ø  A material velocity tolerance error of no more than 20m per second must be
entered into the calculator to maintain a refracted steering angle within +- 1
degrees.

4

Ø  The velocity parameter can be set in the OmniScan MX2 software
in 2 places:
1.  The partweld set up wizard by selecting material with a fixed velocity
from the database. (ProbePart>Part>Material)
2.  The UT>General sub menu by entering a custom velocity value.

Ø  Modifying the velocity will remove any calibration that has been
completed in the wizards because the focal laws must be rebuilt.
Ø  Using the velocity calibration wizard will also automatically
populate the value.

5

Ø  The preferred method for obtaining the velocity in the group set up wizard
is to select the material from a fixed database using a default value.
Ø  When the material velocity is unknown, the MX2 has a velocity calibration
wizard that measures the velocity of a component based on two fixed
reflectors at known positions. (Side drilled hole, radius or back wall)
Ø  Use of the velocity calibration wizard for shear wave inspection is only
beneficial if a suitable calibration block made of the exact same material
has been manufactured.
Ø  This a common practice in pipeline jobs but rarely available for typical
ASME, API, AWS, and similar inspections.

Vs.

6

Ø  For one degree angle accuracy in carbon steel the velocity input to the group set up
wizard (Calculator) must be within +- 20 meterssecond.
Ø  If measuring velocity on a calibration block, 1 degree angle accuracy is only
achieved when the sound path measurement is +- .1mm of the actual value
Ø  Only precision measurements to this tolerance made on a block of the exact same
material will result in velocity accuracy better than a default value taken from the
MX2 database.

7

Ø  The MX2 velocity calibration wizard has 3 options for measuring the velocity
of a component that are compatible with both shear and longitudinal beams.
1.  Radius. (Angle beam on sound path radius)
2.  Depth (Angle beam on side drilled hole)
3.  Thickness (0 degree on component back wall)
Ø 
Ø 
Ø 

All three options require 2 reflectors at known positions.
All three options will achieve best results when used with one A-scan
or focal law. Angle beam is not recommended due to angle error.
Prior to entering the velocity wizard, program at least one single focal
law appropriate for the calibration type or install a conventional UT
probe.

8

Introduction to Phased Array Using the OmniScan MX2 Part 3 – Gate Mode
Ø  Gate mode is set in the Gate
Alarms>Gate>Parameters>Mode sub menu
and determines the point in the gate that is
used for the readings and C-scan data.
Ø  There are 3 measure options for position Cscan and thickness or time of flight related
readings:
–  A. First crossingedge.
–  B. First Peak Position.
–  C. Maximum Peak Position.

Ø  There are 2 peak options for amplitude Cscan and related readings:
–  D. First Peak Amplitude.
–  E. Maximum Peak Amplitude.

Ø  The relative peak and measure mode will be
displayed in the reading box when
applicable.

9

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Readings
Ø 
Ø 
Ø 
Ø 

The readings are relative to the selected A-scan in the group and based on the gate
configuration for either peak or leading edge options.
The volumetric readings are available for gate A and gate B.
Gate A readings are boxed in red and gate B readings are boxed in green.
The full list of available readings and definitions is found in the MX2 software users
manual or online help index.

PA
VIA

DA
SA

10

RA

Ø  Select Wizard>Calibration>Type Ultrasound> Mode Velocity>Start.
Ø  Select Echo Type Thickness> and enter the values for thickness 1 and 2.
Ø  Select Next.

11

Ø  If using a phased array probe, select the focal law used for the measurement.
Ø  Adjust the gain for a signal and ensure that neither target 1 or 2 is saturated.
Ø  Adjust the range over the targets. Excessive range will result in reduced accuracy
due to UT axis resolution based on a fixed point quantity. (MX2 default is 320)

1st backwall at 25mm

2nd backwall at 50mm

12

Ø  Set the gate A start, width, and threshold over thickness 1.
Ø  Select Get Position. The time of flight position of thickness 1 is recorded.

1st backwall at 25mm

13

Ø 
Ø 

Set the gate A start, width, and threshold over thickness 2.
Select Get Position. The time of flight position of thickness 2 is recorded and the
MX2 will calculate the velocity.

2nd backwall at 50mm

14

Ø  Observe the calculated velocity and ensure it is close to the expected value.
Ø  Select Accept.
Ø  The velocity is now set for the active group based on the wizard results.

15

Ø  The OmniScan MX2 user interface displays a status indicator for velocity.

Ø 
Ø 
Ø 

Ø 

A green V indicates that the current velocity in this group was the result of a
measurement made through the velocity calibration wizard.
A green V is not an indicator that the velocity is within tolerance and has no
relevance to code or procedure compliance.
When a velocity other than that in the MX2 database is required, it is normal
practice to measure it one time with a conventional probe and enter it manually for
future inspections.
It is normal and acceptable for inspection .Ops files that have been calibrated for
sensitivity and TCG to have a red V indicating no velocity wizard calibration was
performed.
16

Question:
If the material velocity for the component is unknown and no calibration block of the
exact same material exits, what is the benefit of performing the OmniScan MX2
velocity wizard calibration on an IIW block?
Answer:
There is no benefit. Measuring the velocity of the IIW block does nothing to improve the
accuracy of the inspection because it is not made of the same material as the
component.
Without the calibration block on the left (Or similar design) made of the exact same
material, the MX2 database is just as likely to be correct as a measurement made
from a similar but different component like an IIW block. This function does not
calibrate the instrument, it measures the component velocity.
This is the same principle for conventional UT as well and not unique to phased array
inspection.

VS.

VS.
17

Question:
What is the affect on focal law creation using a wrong or inaccurate material
velocity in the part and setup group wizards?
Answer:
The result is angle, focus, and wedge delay calculation error. Only wedge
delay error can be fixed with the calibration process. Angle and focus error
cannot. Slight angle error due to minor material velocity errors is normal
and affects phased arrays similarly as a a single element probe. This is
typical of conventional UT and can be measured using a standard IIW
calibration block. IIW block angle verification is covered in detail in a later
section.

18

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Wedge Delay
Ø  After completion of the group set up wizard move the probe across the calibration
block visualizing a side drilled hole at a known depth. (20mm below)
Ø  If the hole indication is consistent and at the same depth for all focal laws the
wedge delay is validated to the satisfaction of ASME, AWS, API and similar codes,
a wedge delay wizard correction is not necessary, and ALL the below parameters
will have been verified:

Ø  Wedge velocity.
Ø  Wedge angle.
Ø  Probe element height
and position.
Ø  Material velocity.

20mm SDH

19

Ø  If the SDH depth changes across the focal laws, it is an indication that one or more
of the parameters input into the group wizard were incorrect or out of tolerance
resulting in refracted angle error.
Ø  An incorrect or out of tolerance material velocity error is the most likely parameter
to cause this.
Ø  If the SDH is at a consistent depth that is a little short or long the wedge delay
wizard can make the correction.
Ø  The wedge delay calibration wizard will not correct angle error or velocity error.

Correct wedge delay

Angle or velocity error

20

Introduction to Phased Array Using the OmniScan MX2 Part 3 – Wedge Delay
Ø  The wedge delay calibration wizard is designed to measure and
offset the sound propagation between the probe and the exit point
of the focal law in the wedge. (54.97usec below)
Ø  The function is exactly the same as conventional UT with the
exception that all the variables are available to mathematically
calculate it when exiting the setup group wizard and the function
is performed on many A-scans or focal laws at the same time
instead of just one.

21

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Overview
Ø  When the wedge delay is set correctly, 0mm on the A-scan corresponds to the exit
point of the wedge.
Ø  The sound path propagation through the wedge is delayed out of the A-scan.
Ø  Every focal law has a different wedge delay due to the different angles and exit
point on the wedge.
Ø  Inaccurate wizard input for wedge and probe parameters or failure to calibrate the
wedge delay when needed results in inaccurate time of flight and depth readings.
(SA and DA)

0mm

22

Ø  Inputting the wedge, probe, and component parameters correctly into the
group set up wizard is the most accurate means of arriving at the correct
wedge delay.
Ø  Use of the wedge delay wizard on a new or unworn wedge that was input
correctly into the group set up wizard will not improve the reading
accuracy and is a common source of problems and inaccurate inspection
results.
Ø  Mechanical handling errors and errors due to side drilled holes being
measured at different angles often reduce the accuracy of wedge delay
compared to the calculator results.
Ø  The wedge delay wizard will not correct angle error or velocity error, only
wedge height as pictured below.

23

Ø  The MX2 has wedge delay wizard options for both sound path radius and
true depth side drilled hole (SDH) calibrations.
Ø  The preferred and most accurate method is the sound path radius
calibration because it is not dependent on angle trigonometry and can be
performed over a longer sound path typical of the IIW block below.
Ø  The true depth wedge delay calibration requires a trigonometry calculation
that includes the angle. When the 70 degree is actually 69 it corrupts the
wedge delay calculation when performed on SDHs in true depth mode.
Ø  The calibration block must be of the same material (Same velocity) as the
inspection.

True depth SDH

Sound path radius
24

Ø  The wedge delay wizard will change the UT mode for the range and display based
on the type of calibration reflector that is selected in the wizard.
Ø  If using a standard IIW block, select the UT mode for either true depth or sound path
and adjust the range as follows prior to entering the wizard:

True depth SDH

Sound path radius

True depth scale

Sound path scale

50mm radius

100mm radius

25

15mm SDH

Ø  Be aware of the selected gate measurement mode. (Peaks or edges)
Changing the gate measurement modes after calibration will affect the
readings. The MX2 default is Peaks.
Ø  Enter the wedge delay calibration wizard by selecting
Wizard>Calibration>Type Ultrasound>Mode Wedge Delay>All Angles.
Ø  Select start.
Peak Mode

Edge Mode

26

Ø  Select Echo Type>Radius.
Ø  Enter the radius sound path distance. (50 or 100mm if using standard IIW)

Radius
reflector

27

Ø  Set the position of gate A to cover the radius (Pictured below) or true depth
calibration reflector. The vertical axis of the calibration window is represented by
the gate start and width.
Ø  Set the threshold of gate A to 10% amplitude.

Gate width

100mm
radius

Focal laws and probe movement

28

Ø  Select Clear Envelope and move the probe across the calibration block passing
each focal law through the 100mm radius maximum amplitude position.
Ø  The white envelope trace represents the position in mm for the maximum amplitude
signal for each focal law.
Ø  Prior to calibration the 57 degree focal law is reading 104mm in sound path. The
calibration wizard will correct each focal law to 100mm sound path by modifying the
the beam delay that was originally calculated by the group set up wizard. (UT
Settings>Beam>Beam Delay)
Ø  Select Calibrate.

57 degree focal law

29

Ø  After selecting calibrate, move the probe over the block again passing each focal
law through the 100mm radius maximum amplitude position to verify that the wedge
delay was modified correctly.
Ø  If the wedge delay calibration was successful the new white envelope trace will be
contained within the tolerance window indicating all focal laws are detecting the
100mm radius +/- 1mm.
Ø  Calibrate can be selected repeatedly improving the calibration until the white
envelope trace is contained within the +/- 1mm tolerance.
Ø 

Select Accept and a green W is
displayed in the MX2 indication area
indicating that the wedge delay has been
modified by the calibration wizard.

55 degree focal law

30

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Amplitude
Ø  The A-scan is the data view from which all other views are based. The B-scan
S-scan, and C-scab convert amplitude to color coded pixels based on the 2D
views.
Ø  The C-scan can be configured for an amplitude or position 2D representation
of the A-scan data.
Ø  The ruler to the right displays the MX2 default amplitude color palette. 0 -100%
amplitude vs. a scaled color palette typical of amplitude based acceptance
criteria.

31

Introduction to Phased Array Using the OmniScan MX2 Part 3 - Sensitivity
Ø 

Ø 
Ø 

Ø 

The MX2 sensitivity calibration wizard is designed to equalize the
amplitude of all A-scans or focal laws in the group on one calibration
target. Typically an IDOD notch or side drilled hole in a reference
block.
This function is also called ACG by the ASME codes. (Angle
corrected gain)
In conventional UT, sensitivity calibration is achieved by manually
adjusting the gain until the reflected signal is at a predetermined
amplitude, typically 80%.
The function of the sensitivity wizard is to record the amplitude of
every A-scan or focal law on the calibration target and automatically
adjust the focal law gain offsets to the desired amplitude, typically
80%.

32


33

Ø 
Ø 

Prior to sensitivity calibration lower angles will detect the target at a higher amplitude
than the higher angles due to a longer sound path and more attenuation.
Without sensitivity calibration defects can be missed and all focal laws cannot be
used for code required amplitude based acceptance criteria such as ASME section V
and similar.

34
25.7 Total dB (No sensitivity calibration)

25.7 Total dB (No sensitivity calibration)

Ø 
Ø 

In the examples below, the MX2 general gain of 24.1dB is applied to all focal laws in
the group.
After completion of the sensitivity calibration wizard each focal law applies a
calibrated gain offset that is added to the general gain to achieve the required
sensitivity, typically 80% amplitude.

24.1 dB + 1.6 dB = 25.7 Total dB 35

24.1 dB + 9.2 dB = 33.3 Total dB


36

6mm
12mm

20mm

Ø  The target used for sensitivity calibration should be in the general range of the
area of interest for the inspection and specified in the work procedure.
Ø  A general rule of thumb for weld inspection is to use the closest calibration target
available that is at least 1.5 times the skip thickness in true depth.
Ø  SDH selection for sensitivity calibration that is too shallow or too deep results in
poor inspection results and may impede TCG construction.

Ø  After completing the group setup wizard process, position the probe so
that the calibration target can be seen in the S-scan. (15mm SDH from IIW
as pictured below)
Ø  Ensure that the range is sufficient for the target on all focal laws. (45-70
degrees)
Ø  Enter the wizard to calibrate the S-scan for sensitivity (ACG) by selecting
Wizard>Calibration>Type Ultrasound>Mode Sensitivity>All Angles.
Ø  Select start.

37

Ø  Enter the reference amplitude. (default 80%) All focal laws will be
adjusted to this amplitude by addition of a focal law gain offset after
sensitivity wizard completion.
Ø  Enter tolerance. The tolerance is a visual indicator for amplitude
verification after the sensitivity calibration correction. In the example
below a tolerance of 5% on an 80% calibration would place the window
from 77.5% to 82.5%.

5% tolerance window
Amplitude envelope

38

Ø  Select the last focal law to be calibrated for sensitivity. When there are no
obstructions from corners or adjacent calibration targets the entire sector scan can
be calibrated at one time.
Ø  Excluding a portion of the S-scan as pictured to the right will allow the calibration to
be completed in sections where the gate can be repositioned to avoid interference
from corners of the block or adjacent calibration targets if necessary.

Focal law
45-70

Focal law
45-60

39

Focal law
61-70

Ø  Set the start and width of gate A to ensure that the calibration target can be detected
by all focal laws in the S-scan.
Ø  Set the gate A threshold as low as possible to ensure the last focal law can be
detected. Gate thresholds below approximately 10% may have an amplitude error
beyond the tolerance when the focal law gain offset is calculated to correct to 80%.

Gate A

Gate A

Gate A

40

Ø  Gain compensation is a tool that is used to ease calibration. Use of gain
compensation will allow a wider sector (50-65 degrees vs. 45-70 degrees) and will
also allow calibration on a target with a longer sound path.
Ø  When gain compensation is selected in the example below, a 2dB per usec
correction is added to each focal law in addition to the 14dB of general gain.
Ø  The longer the sound path to the calibration target, the more gain is added. (70
degrees receives more gain than 45 degrees)
Ø  The MX2 default is 2dBusec for sector scans and .2dBusec for linear angle and
can be manually adjusted.
Ø  Select Apply and select Next.

2dB
2dB
2dB

2dB

41

2dB

Ø  Move the probe across the calibration block with consistent pressure and coupling.
Ø  As the calibration target travels through the gate of each focal law the green
envelope records the maximum amplitude detected.
Ø  The MX2 will calculate the required gain offset in dB for each focal law to correct to
80%. Focal laws with amplitude over 80% but less than 100% will receive a
negative gain offset.
Ø  Do not select Calibrate yet.
Ø  Continue to next slide.

42

Ø  The green envelope should be smooth and consistent without any radical changes
in amplitude between focal laws.
Ø  No focal law can be higher than 100% amplitude and the lowest focal law must be
higher than approximately 10% amplitude prior to selecting calibrate.
Ø  This ratio equates to approximately 20dB. The highest and lowest focal laws must
be within approx. 20dB of each other for the sensitivity wizard to function.
Ø  If the amplitude envelope cannot be completed with a <100% and >10% ratio the
angular range of the S-scan must be reduced. (Reduce S-scan from 30-75 degrees
to 45-70 degrees)
Ø  The longer the sound path and/or smaller the calibration target, the greater dB
difference between the first and last focal laws of an S-scan calibration.
Ø  If the green envelope was not created
properly select clear envelope and repeat the
probe movement.
Ø  Select Calibrate. After sensitivity calibration
a focal law offset is created in
UT>Beam>GainOffset for every focal law.

43

Ø  Successful sensitivity calibration of the S-scan is visualized by repeating the probe
movement over the calibration block with all focal laws corrected to 80% amplitude
within the tolerance.
Ø  If any focal law is over 100% after calibration the complete process must be
repeated by selecting Restart. Saturated focal laws cannot be corrected.
Ø  Calibrate may be selected repeatedly until all laws are within tolerance.
Ø  Select Accept when satisfactory and a green S will appear in the MX2 indication
area indicating the sensitivity was completed.

44

Ø 

Ø 

Ø 

Ø 

The MX2 sensitivity calibration wizard can be performed on all laws as
in the previous section and can also interpolate the curve for the S-scan
calibration based on 2 or 3 focal laws.
When 2 or 3 focal laws are selected the wizard will record the amplitude
value of only the selected focal laws to make a linear interpolation of the
focal law gain offsets for the remaining laws.
In other words, if the focal law gain offset of 2 or 3 focal laws is known
based on real readings, the focal law gain offset of the remaining laws
can be predicted with a linear interpolation.
This feature is most accurate when the first and last focal laws of the Sscan are selected.

45

Ø  Select either 2 or 3 for the quantity of focal laws to be used for the
calibration.
Ø  Enter the focal laws or angles that will be used. In this example we are
using 3 focal laws representing the first, middle, and last focal laws of the
S-scan. (45, 55, and 70 degrees in the example below)

46

Ø  Move the probe to peak the selected focal laws for maximum amplitude
and verify that each of the three has been corrected within the tolerance.
Ø  Select Accept. The software corrects all the focal law gain offsets for the
S-scan to 80% amplitude with a linear interpolation based on the three
readings at 45, 55, and 70 degrees.
Ø  The MX2 indication area will display a green Si indicating the calibration
was performed using an interpolation of 2 or 3 focal laws.

47

Introduction to Phased Array Using the OmniScan MX2 Part 3 - TCG
Ø  What is the affect on a one line S-scan inspection without a TCG
calibration?
–  It is impossible to set the inspection sensitivity where flaws are detected at a similar amplitude
throughout the weld volume and flaws are missed or are detected over sensitive.
–  The C-scan on the left was acquired with a TCG calibration and the C-scan on the right with only a
sensitivity calibration. Both the color and amplitude for the TCG C-scan is consistent and flaws
appearing at different positions in the weld will be detected similarly.

Ø  The ease at which flaws are detected, characterized, and sized in analysis
is directly related to the quality of the sensitivity and TCG calibrations.
45-70 degree S-scan with TCG

45-70 degree S-scan without TCG

48

Ø  What is the difference between a TCG (Time corrected Gain) and DAC (Distance
amplitude correction) with regard to the inspection results?
–  No difference. They are designed to arrive at the same defect rate and sizing.
This is the same as conventional UT and a TCG is preferred over a DAC
because it is compatible with an amplitude color palette for the full range.
Ø  What is the difference between a TCG and DAC with regard to code compliance?
–  No difference. DAC and TCG are synonymous with respect to code compliance
and where one is specified either may be used. The result of a DAC is the same
but dependent on visualizing the A-scan, not the color palette.

49

Ø  Set the start and width of gate A to ensure that the calibration target can be detected
by all focal laws in the S-scan.
Ø  Set the gate A threshold as low as possible to ensure the last focal law can be
detected. Gate thresholds below approximately 10% may have an amplitude error
beyond the tolerance when the focal law gain offset is calculated to correct to 80%.

Gate A

Gate A

Gate A

50

Ø  Move the probe across the calibration block again with the same pressure and
couplant to ensure that every focal law for this TCG point was corrected to 80%.
Ø  Select next point and repeat the process for successive TCG points until complete.
Ø  If after adding a point it is unable to be verified within the tolerance window select
cancel point and repeat the process for that point.
Ø  Upon completion of the last TCG point select accept TCG.

51

Ø  What is the total gain applied to the 60 degree focal law on the fourth
TCG point at 25mm?

52

Ø  What is the total gain applied to the 60 degree focal law on the fourth TCG
point for 25mm side drilled hole?
–  Completion of the normal sensitivity and TCG wizard calibration process will
result in the following:
General gain (37.7dB) + focal law gain offset (0.1dB) + TCG point 4 (8.1dB) =
45.9dB
UT>General>Gain

UT>General>Beam>Gain Offset

Sizing>Curve Setup>Current Law>Point 4> TCG Gain

53

Thank You!

Please send questions and comments to: PhasedArraySupport@olympusndt.com

www.olympus-ims.com

Introduction to Phased Array Using the OmniScan MX2 - Part Three

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Introduction to Phased Array Using the OmniScan MX2 - Part Three